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Numerous studies have shown that the non-destructive testing has proved the exceptional role in supervising the quality of concrete. Today, they represent an alternative that contributes to the resolution of materials diagnostic problems without altering them. This work presents an experimental study using a pulse-echo method that has the advantage of generating two types of wave (compressional and shear) by a mode conversion using just one transducer. The samples were made in a prismatic form. The results recovered from backscattered echoes are extracted using an estimation algorithm. These data were exploited to determine velocities of the tested material then the reflection coefficients for related them with the compressive strength. The tests were conducted with six samples with varied water/cement ratio. The results obtained showed that the prism technique has the potential to evaluate characteristics cementitious material using this proposed process.
Czasopismo
Rocznik
Tom
Strony
196--212
Opis fizyczny
Bibliogr. 29 poz., fot., rys., tab., wykr.
Twórcy
autor
- Department of civil engineering, LGCE Laboratory, University of MSB Jijel
autor
- Department of civil engineering, NDT Laboratory, University of MSB Jijel
autor
- Department of electronics, NDT Laboratory, University of MSB Jijel
autor
- Department of civil engineering, MGE Laboratory, University of BM Annaba
Bibliografia
- 1. Abo-Qudais, SA 2005. Effect of concrete mixing parameters on propagation of ultrasonic waves. Construction and Building Materials 19, 257-263.
- 2. Aggelis, DG, De Sutter, S, Verbruggen, S, Tsangouri, E and Tysmans, T 2019. Acoustic emission characterization of damage sources of lightweight hybrid concrete beams. Engineering Fracture Mechanics 210, 181-188.
- 3. AI-Akhras, NM and AI-Qadi, IL 1998. Using ultrasonic waves to detect basic properties of Portland cement concrete. The Indian Concrete Journal, 72 (1), 33-37.
- 4. Al-Mufti, RL and Fried, AN 2012. The early age non-destructive testing of concrete made with recycled concrete aggregate. Construction and Building Materials 37, 379-386.
- 5. Blitz, J 1997. Electrical and magnetic methods of non-destructive testing, Second Edition, Springer Netherlands.
- 6. Bouhadjera, A and Bouzrira, C 2005. High-frequency ultrasonic testing of young cement-based materials using the 'prism technique'. NDT&E International 38, 135-142.
- 7. Boumiz, A, Vernet, C and CohenTenoudji, F 1996. Mechanical properties of cement pastes and mortars at early ages: Evolution with time and degree of hydration. Advanced Cement Based Materials 3 (3-4), 94-106.
- 8. Briggs, GAD and Kolosov, OV 2010. Acoustic microscopy, Second Edition, Oxford University Press.
- 9. Brozovsky, J 2014. High-strength concrete - NDT with rebound hammer: influence of aggregate on test results. Nondestructive Testing and Evaluation 29(3), 255-268.
- 10. David, J and Cheeke, N 2002. Fundamental and applications of ultrasonic waves, Second Edition, CRC Press New York, USA.
- 11. Dinh, K, Gucunski, N and Zayed, T 2019. Automated visualization of concrete bridge deck condition from GPR data. NDT & E International 102, 120-128.
- 12. Grimes, M, Bouhadjera, A, Haddad, S and Benkedidah, T 2012. In vitro estimation of fast and slow wave parameters of thin trabecular bone using space-alternating generalized expectation-maximization algorithm. Ultrasonics 52, 614-621.
- 13. Hellier, C 2003. Handbook of nondestructive evaluation, Second Edition, McGraw-Hill Education, USA.
- 14. Hermida, G 2008. Influence of paste volume and cement content upon concrete performance: toward the development of concrete with minimized paste, Ph.D. Cachan ENS.
- 15. Hernandez, MG, Izquierdo, MAG, Ibanez, A, Anaya, JJ and Ullate, LG 2000. Porosity estimation of concrete by ultrasonic NDE. Ultrasonics 38, 531-533.
- 16. Hussain, A and Akhtar, S 2017. Review of Non-Destructive Tests for Evaluation of Historic Masonry and Concrete Structures. Arabian Journal for Science and Engineering 42(3), 925-940.
- 17. Kheder, GF, Al Gabban, AM and Abid, SM 2003. Mathematical model for the prediction of cement compressive strength at the ages of 7 and 28 days within 24 hours. Materials and Structures 36, 693-701.
- 18. Krauträmer, H and Krauträmer, J 1990. Ultrasonic testing of materials, 4rd Edition, Springer-Verlag: Berlin, Heidelberg, New York.
- 19. Kundu, T 2003. Ultrasonic nondestructive evaluation: Engineering and Biological Material Characterization, CRC Press London.
- 20. Merdjana, H, Boukabou, A and Grimes, M 2018. A high accuracy ultrasonic measurement system using the prism technique. Measurement 114, 195-202.
- 21. Mix, PE 2005. Introduction to nondestructive testing: A training guide, Second Edition, John Wiley & Sons, USA.
- 22. Panzera, TH, Rubio, JC, Bowen CR, Vasconcelos, WL and Strecker, K. 2008. Correlation between structure and pulse velocity of cementitious composites. Advances in Cement Research 20 (3), 101-108.
- 23. Payan, C, Abraham, O and Garnier, V 2018. Ultrasonic methods, Nondestructive testing and Evaluation of Civil Engineering Structures, 21-85.
- 24. Qasrawi, HY 2000. Concrete strength by combined nondestructive methods simply and reliably predicted. Cement and Concrete Research 30, 739-746.
- 25. Soltani, F 2010. Characterization of cement paste by ultrasonic methods, Ph.D. EC-Lille.
- 26. Trtnik, G, Kavčič and F, Turk, G 2009. Prediction of concrete strength using ultrasonic pulse velocity and artificial neural networks. Ultrasonics 49, 53-60.
- 27. Turgut, P and Kucuk, OF 2006. Comparative relationships of direct, indirect, and semi-direct ultrasonic pulse velocity measurements in concrete. Russian Journal of Nondestructive Testing 42 (11), 745-751.
- 28. Uddin, MT and Mahmood, AH 2016. Effects of maximum aggregate size on UPV of brick aggregate concrete. Ultrasonics 69, 129-136.
- 29. Voigt, T 2005. The Application of an ultrasonic shear wave reflection method for nondestructive testing of cement-based materials at early ages: An experimental and numerical analysis, University of Leipzig, Germany, Books on Demand.
Uwagi
PL
Opracowanie rekordu ze środków MNiSW, umowa Nr 461252 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2020).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-02f7f5b2-1733-4912-8ba9-edfc00ba7613