A novel formulation of 3D spectral element for wave propagation in reinforced concrete - Publication - Bridge of Knowledge

Your account

login

Search

A novel formulation of 3D spectral element for wave propagation in reinforced concrete

Abstract

The paper deals with numerical simulations of wave propagation in reinforced concrete for damage detection purposes. A novel formulation of a 3D spectral element was proposed. The reinforcement modelled as the truss spectral element was embedded in the 3D solid spectral finite element. Numerical simulations have been conducted on cuboid concrete specimens reinforced with two steel bars. Different degradation models were considered to study the real behaviour of bended beams.

Citations

  • 2

    CrossRef

  • 0

    Web of Science

  • 5

    Scopus

Authors (5)

Cite as

Full text

download paper
downloaded 32 times
Publication version
Accepted or Published Version
License
Creative Commons: CC-BY-NC-ND open in new tab

Keywords

Details

Category:
Articles
Type:
artykuł w czasopiśmie wyróżnionym w JCR
Published in:
Bulletin of the Polish Academy of Sciences-Technical Sciences no. 65, pages 805 - 813,
ISSN: 0239-7528
Language:
English
Publication year:
2017
Bibliographic description:
Rucka M., Witkowski W., Chróścielewski J., Burzyński S., Wilde K.: A novel formulation of 3D spectral element for wave propagation in reinforced concrete// Bulletin of the Polish Academy of Sciences-Technical Sciences. -Vol. 65, nr. 6 (2017), s.805-813
DOI:
Digital Object Identifier (open in new tab) 10.1515/bpasts-2017-0089
Bibliography: test
  1. V. Srinivas, S. Sasmal, K. Ramanjaneyulu, and C. Antony Jeyase- har, "Influence of test conditions on modal characteristics of rein- forced concrete structures under different damage scenarios", Ar- chives of Civil and Mechanical Engineering 13, 491-505 (2013). open in new tab
  2. V. Pérez-Gracia and F. García García, I. Rodriguez Abad, "GPR evaluation of the damage found in the reinforced concrete base of a block of flats: A case study", NDT&E International 41, 341-353 (2008). open in new tab
  3. K. Ohno and M. Ohtsu, "Crack classification in concrete based on acoustic emission", Construction and Building Materials 24, 2339-2346 (2010). open in new tab
  4. Fig. 12. Numerical wave propagation time signals registered at point 2 for reinforced concrete specimens with various damage scenarios A novel formulation of 3D spectral element for wave propagation in reinforced concrete
  5. C.-C. Cheng, T.-M. Cheng, and C.-H. Chiang, "Defect detection of concrete structures using both infrared thermography and elas- tic waves", Automation in Construction 18, 87-92 (2008). open in new tab
  6. D.G. Aggelis and T. Shiotani, "Repair evaluation of concrete cracks using surface and through-transmission wave measure- ments", Cement & Concrete Composites 29, 700-711 (2007). open in new tab
  7. J. Hoła, Ł. Sadowski, and K. Schabowicz, "Nondestructive iden- tification of delaminations in concrete floor toppings with acous- tic methods", Automation in Construction 20, 799-807 (2011).
  8. Y. Yang, G. Cascante, and M.A. Polak, "Depth detection of sur- face-breathing crack in concrete plates using fundamental Lamb modes", NDT&E International 42, 501-512 (2009). open in new tab
  9. J. Hoła, J. Bień, Ł. Sadowski, and K. Schabowicz, "Non-destruc- tive and semi-destructive diagnostics of concrete structures in assessment of their durability", Bulletin of the Polish Academy of Sciences Technical Sciences 63, 87-96 (2015). open in new tab
  10. A. Garbacz, "Application of stress based NDT methods for con- crete repair bond quality control", Bulletin of the Polish Academy of Sciences Technical Sciences 63, 77-85 (2015). open in new tab
  11. M. Rucka and K. Wilde, "Experimental study on ultrasonic mon- itoring of splitting failure in reinforced concrete", Journal of Nondestructive Evaluation 32, 372-383 (2013). open in new tab
  12. M. Rucka and K. Wilde, "Ultrasound monitoring for evaluation of damage in reinforced concrete", Bulletin of the Polish Acad- emy of Sciences: Technical Sciences 63, 1-11 (2015). open in new tab
  13. B.S. Divsholi and Y. Yang, "Combined embedded and sur- face-bonded piezoelectric transducers for monitoring of concrete structures", NDT&E International 65, 28-34 (2014).
  14. F. Moradi-Marani, P. Rivard, C.-P. Lamarche, and S.A. Kodjo, "Evaluating the damage in reinforced concrete slabs under bend- ing test with the energy of ultrasonic waves", Construction and Building Materials 73, 663-673 (2014). open in new tab
  15. M. Rucka. "Experimental and numerical studies of guided wave damage detection in bars with structural discontinuities", Archive of Applied Mechanics 80, 1371-1390 (2010). open in new tab
  16. M. Rucka. "Modelling of in-plane wave propagation in a plate using spectral element method and Kane-Mindlin theory with application to damage detection", Archive of Applied Mechanics 81, 1877-1888 (2011). open in new tab
  17. T. Patera, "A spectral element method for fluid dynamics: lam- inar flow in a channel expansion", Journal of Computational Physics 54, 468-488 (1984). open in new tab
  18. J. F. Semblat and J. J. Brioist, "Efficiency of higher order finite elements for the analysis of seismic wave propagation", Journal of Sound and Vibration 231, 460-467 (2000). open in new tab
  19. D. Komatitsch, R. Martin, J. Tromp, M.A. Taylor, and B.A. Win- gate, "Wave propagation in 2-D elastic media using a spectral element method with triangles and quadrangles", Journal of Computational Acoustics 9, 703-718 (2001). open in new tab
  20. W. Ostachowicz, P. Kudela, M. Krawczuk, and A. Żak Guided Waves in Structures for SHM: The Time-Domain Spectral Ele- ment Method, Wiley, 2012. open in new tab
  21. A. Żak, M. Krawczuk, and W. Ostachowicz, "Propagation of in- plane wave in an isotropic panel with a crack", Finite Elements in Analysis and Design 42, 929-941 (2006).
  22. M. Rucka, W. Witkowski, J. Chróscielewski, and K. Wilde, "Dam- age detection of a T-shaped panel by wave propagation analysis in the plane stress", Archives of Civil Engineering LVIII(1), 3-24 (2012). open in new tab
  23. J. Chróścielewski, M. Rucka, W. Witkowski, and K. Wilde, "For- mulation of spectral truss element for guided waves damage de- tection in spatial steel trusses", Archives of Civil Engineering LV(1), 43-63 (2009).
  24. A. Żak, "A novel formulation of a spectral plate element for wave propagation in isotropic structures", Finite Elements in Analysis and Design 45, 650-658 (2009). open in new tab
  25. Y. Liu, N.Hu, C.Yan, X.Peng, and B.Yan, "Construction of a Mindlin pseudospectral plate element and evaluating efficiency of the element", Finite Elements in Analysis and Design 45, 538-546 (2009). open in new tab
  26. W. Witkowski, M. Rucka, J. Chróścielewski, and K. Wilde, "Wave propagation analysis in spatial frames using spectral Timoshenko beam elements in the context of damage detection". Archives of Civil Engineering LV(3), 367-402 (2009). open in new tab
  27. A. Żak and M. Krawczuk, "Certain numerical issues of wave propagation modelling in rods by the Spectral Finite Element Method", Finite Elements in Analysis and Design 47, 1036-1046 (2011). open in new tab
  28. L. Ge, X. Wang, and C. Jin, "Numerical modelling of PZT-in- duced Lamb wave-based crack detection in plate-like structures", Wave Motion 51, 867-885 (2014). open in new tab
  29. H. Peng, Meng G., and F. Li, "Modeling of wave propagation in plate structures using three-dimensional spectral element method for damage detection", Journal of Sound and Vibration 320, 942-954 (2009). open in new tab
  30. A. Żak, M. Krawczuk, Ł. Skarbek, and M. Palacz, "Numerical analysis of elastic wave propagation in unbounded structures", Finite Elements in Analysis and Design 90, 1-10 (2014). open in new tab
  31. D.M. Joglekar and M. Mitra, "Nonlinear analysis of flexural wave propagation through 1D waveguides with breathing crack", Journal of Sound and Vibration 344, 242-257 (2015). open in new tab
  32. R. Sridhar, A. Chakraborty, and S. Gopalakrishnan, "Wave propa- gation analysis in anisotropic and inhomogeneous uncracked and cracked structures using pseudospectral finite element method", International Journal of Solids and Structures 43, 4997-5031 (2006). open in new tab
  33. O.C. Zienkiewicz and R.L. Taylor, The Finite Element Method, Butterworth-Heinemann, 2000. open in new tab
  34. T.J.R. Hughes, The Finite Element Method: linear static and dynamics finite element analysis, Dover Publications, Inc., New York, 2000.
  35. W. Witkowski, M. Rucka, J. Chróścielewski, and K. Wilde, "On some properties of 2D spectral finite elements in problems of wave propagation", Finite Elements in Analysis and Design 55, 31-41 (2012). open in new tab
  36. M. Koizumi, "FGM activities in Japan", Composites Part B 28B, 1-4 (1997). open in new tab
  37. J. Woo and S. A. Meguid, "Nonlinear analysis of functionally graded plates and shallow shells", International Journal of Solids and Structures 38, 7409-7421, (2001). open in new tab
Verified by:
Gdańsk University of Technology

seen 133 times

Recommended for you

Experimental and numerical investigations for GPR evaluation of reinforced concrete footbridge

2016

Reference-free determination of debonding length in reinforced concrete beams using guided wave propagation

2019

Ultrasound monitoring for evaluation of damage in reinforced concrete

2015

3-D finite-difference time-domain modelling of ground penetrating radar for identification of rebars in complex reinforced concrete structures

2018
Meta Tags