[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.12989/sem.2018.68.3.335

Material structure generation of concrete and its further usage in numerical simulations

Husek, Martin (Institute of Structural Mechanics, Faculty of Civil Engineering, Brno University of Technology)
Kala, Jiri (Institute of Structural Mechanics, Faculty of Civil Engineering, Brno University of Technology)

Publication Information

Structural Engineering and Mechanics / v.68, no.3, 2018 , pp. 335-344 More about this Journal

Abstract

The execution of an experiment is a complex affair. It includes the preparation of test specimens, the measurement process itself and also the evaluation of the experiment as such. Financial requirements can differ significantly. In contrast, the cost of numerical simulations can be negligible, but what is the credibility of a simulated experiment? Discussions frequently arise concerning the methodology used in simulations, and particularly over the geometric model used. Simplification, rounding or the complete omission of details are frequent reasons for differences that occur between simulation results and the results of executed experiments. However, the creation of a very complex geometry, perhaps all the way down to the resolution of the very structure of the material, can be complicated. The subject of the article is therefore a means of creating the material structure of concrete contained in a test specimen. Because a complex approach is taken right from the very start of the numerical simulation, maximum agreement with experimental results can be achieved. With regard to the automation of the process described, countless material structures can be generated and randomly produced samples simulated in this way. Subsequently, a certain degree of randomness can be observed in the results obtained, e.g., the shape of the failure - just as is the case with experiments. The first part of the article presents a description of a complex approach to the creation of a geometry representing real concrete test specimens. The second part presents a practical application in which the numerical simulation of the compressive testing of concrete is executed using the generated geometry.

Keywords

heterogeneity; material structure; noise; pressure test; smoothed particle hydrodynamics;

Citations & Related Records

Times Cited By KSCI : 3 (Citation Analysis)

Reference
Cited By KSCI

1	Karperien, A.B. (2013), FracLac for ImageJ, .
2	Kessenich J., Sellers G. and Shreiner D. (2017), OpenGL Programming Guide, Addison-Wesley, Boston, Massachusetts, U.S.A.
3	Kral, P., Kala, J. and Hradil, P. (2016), "Verification of the elastoplastic behavior of nonlinear concrete material models", Int. J. Mech., 10, 175-181.
4	Kralik, J., Klabnik, M. and Grmanova, A. (2015), "Probability analysis of a composite steel and concrete column loaded by fire", Appl. Mech. Mater., 769, 126-132. DOI
5	Liu, G.R. and Liu, M.B. (2003), Smoothed Particle Hydrodynamics: A Meshfree Particle Method, New Jersey: World Scientific, Hackensack, Bergen County, U.S.A.
6	Livermore Software Technology Corporation (2017), LS-DYNA Theory Manual, LSTC, Livermore, California, U.S.A.
7	McIntyre, N.E. and Wiens, J.A. (2000), "A novel use of the lacunarity index to discern landscape function", Landsc. Ecol., 15(4), 313-321. DOI
8	Miyamoto, A. and Isoda, S. (2012), "Sensitivity analysis of mechanical behaviors for bridge damage assessment", Struct. Eng. Mech., 41(4), 539-558. DOI
9	Moes, N., Dolbow, J. and Belytschko, T. (1999), "A finite element method for crack growth without remeshing", Int. J. Numer. Meth. Eng., 46(1), 131-150. DOI
10	Murray, Y.D. (2007), User's Manual for LS-DYNA Concrete Material Model 159, FHWA-HRT-05-062.
11	Murray, Y.D., Abu-Odeh, A. and Bligh, R. (2007), Evaluation of Concrete Material Model 159, FHWA-HRT-05-063.
12	Plotnick, R.E., Gardner, R.H., Hargrove, W.W., Prestegaard, K. and Perlmutter, M. (1996), "Lacunarity analysis: A general technique for the analysis of spatial patterns", Phys. Rev. E, 53(5), 5461-5468.
13	Nam, J.W., Yoon, I.S. and Yi, S.T. (2016), "Numerical evaluation of FRP composite retrofitted reinforced concrete wall subjected to blast load", Comput. Concrete, 17(2), 215-225. DOI
14	Perlin, K. (1985), "An image synthesizer", ACM SIGGRAPH Comput. Graph., 19(3), 287-296. DOI
15	Plotnick, R.E., Gardner, R.H. and O'Neill, R.V. (1993), "Lacunarity indices as measures of landscape texture", Landsc. Ecol., 8(3), 201-211. DOI
16	Rahmanian, I., Lucet, Y. and Tesfamariam, S. (2014), "Optimal design of reinforced concrete beams: A review", Comput. Concrete, 13(4), 457-482. DOI
17	Smith, T.G., Lange, G.D. and Marks, W.B. (1996), "Fractal methods and results in cellular morphology-dimensions, lacunarity and multifractals", J. Neurosci. Meth., 69(2), 123-136. DOI
18	Willam, K. and Carol, I. (1995), "Discrete Versus smeared crack analysis", Proceedings of the 2nd International Association of Fracture Mechanics for Concrete and Concrete Structures, Zurich, Switzerland.
19	Swegle, J.W., Hicks, D.L. and Attaway, S.W. (1995), "Smoothed particle hydrodynamics stability analysis", J. Comput. Phys., 116(1), 123-134. DOI
20	Vivo, P.G. and Lowe, J. (2015), The Book of Shaders, .
21	Bazant, Z. and Ozbolt, J. (1990), "Non-local microplane model for fracture, damage and size effect in structures", J. Eng. Mech., 128(11), 1119-1149.
22	Agrawal, R. and Hora. M.S. (2012), "Nonlinear interaction behaviour of infilled frame-isolated footings-soil system subjected to seismic loading", Struct. Eng. Mech. J., 44(1), 85-107.
23	Aurenhammer, F. (1991), "Voronoi diagrams-a survey of a fundamental geometric data structure", ACM Comput. Surv., 23(3), 345-405. DOI
24	Bazant, Z. (1984), "Microplane model for strain-controlled inelastic behavior", Mech. Eng. Mater., 45-59.
25	Hokes, F., Kala, J. and Krnavek, O. (2016), "Nonlinear numerical simulation of a fracture test with use of optimization for identification of material parameters", Int. J. Mech., 10, 159-166.
26	Belytschko, T., Guo, Y., Liu, W.K. and Xiao, P. (2000), "A unified stability analysis of meshless particle methods", Int. J. Numer. Meth. Eng., 48(9), 1359-1400. DOI
27	Benz, W. (1989), Smoothed Particle Hydrodynamics: A Review, NATO Workshop.
28	Han, J., Zhao, X., Tang, Z., Ma, H. and Li, Z. (2017), "Study on the bearing capacity of cold-formed steel under different boundary conditions in transmission towers", Earthq. Struct., 12(6), 665-672. DOI
29	Husek, M., Kala, J., Kral, P. and Hokes, F. (2016), "Effect of the support domain size in SPH fracture simulations", Int. J. Mech., 10, 396-402.
30	Husek, M., Hokes, F., Kala, J. and Kral, P. (2017), "Inclusion of Randomness into SPH Simulations", WSEAS Trans. Heat Mass Transfer, 12, 1-10.
31	Kala, J. and Husek, M. (2016a), "Improved element erosion function for concrete-like materials with the SPH method", Shock Vibr., 1-13.
32	Kala, J. and Husek, M. (2016b), "High speed loading of concrete constructions with transformation of eroded mass into the SPH", Int. J. Mech., 10, 145-150.
33	Kala, Z. (2016), "Global sensitivity analysis in stability problems of steel frame structures", J. Civil Eng. Manage., 22(3), 417-424. DOI
34	Karperien, A.B. (2004), "Defining microglial morphology: Form, function, and fractal dimension", Ph.D. Dissertation, Charles Sturt University, Sydney, Australia.