Simulation of the Slump Test Based on the Discrete Element Method (DEM)

Hooman Hoornahad; Eduard A. B. Koenders

doi:10.4028/www.scientific.net/AMR.446-449.3766

Paper Titles

Finite Element Modelling for Characterizing some Dynamical Properties of a Masonry Building Prototype
p.3745

Thermal Properties of Vacuum Insulation Panels with Glass Fiber
p.3753

Numerical Simulation of Subway Station Constructed Using Top-Down Method
p.3757

Applications of Data Mining in CRM Based on Web Log
p.3762

Simulation of the Slump Test Based on the Discrete Element Method (DEM)
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Numerical Simulation on Penetration Properties of Concrete Based on Random Particle Model
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An Investigation of Procedures of Change Orders’ Control in Roadway Construction Projects
p.3778

Forecast on Payback Period of Restaurant Projects Investment by Computer Simulation
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Bounday-Layer Asymptotics on the Contact Interface in the Impact Problem
p.3787

HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 446-449Simulation of the Slump Test Based on the Discrete...

Simulation of the Slump Test Based on the Discrete Element Method (DEM)

Abstract:

The slump test is a very important industrial test for evaluation of workability of fresh granular-cement paste material, especially concrete. The test method is used as a generic tool for classification of a wide range of mixtures and can deal with a wide range of workabilities. The current paper presents a numerical approach, based on Discrete Element Method (DEM), with the aim to study the effect of the mix composition on the rheological behavior of a mixture after demolding, i.e. lifting the slump cone. The research approach is based on a conceptual idea, where the particle-paste interaction is explicitly modelled as an interactive two phase “paste –particle” system. Each mixture is considered to consist of these elements with the rheological behaviour characterized by the “excess paste” model. Simulations and experimental laboratory test results show good agreement.

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Periodical:

Advanced Materials Research (Volumes 446-449)

Pages:

3766-3773

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.446-449.3766

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Online since:

January 2012

Authors:

Hooman Hoornahad, Eduard A. B. Koenders

Keywords:

Discrete Element Method (DEM), Fresh Granular-Cement Paste, Simulation, Two Phase Model

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References

[1] ACI Committee 116R: Cement and Concrete Terminology (ACI Manual of Concrete Practice, Detroit, MI 2000)

Google Scholar

[2] G. S. Wong, A. M. Alexander, R. Haskins, T. S. Poole, P. G. Malone, and L. Wakeley: Portland- Cement Concrete Rheology and Workability: Final Report (Structures Laboratory, USAE Research and Development Center (ERDC) 2001)

Google Scholar

[3] V. Hackley and C.F. Ferraris: The Use of Nomenclature in Dispersion Science and Technology : Special Report 960-3(Gaithersburg, MD: National Institute of Standards and Technology 2001)

Google Scholar

[4] N. Roussel, M. R. Geiker, F. Dufour, L. N. Thrane and P. Szabo: Cement and Concrete Research 37 (2007), p.1298

DOI: 10.1016/j.cemconres.2007.06.007

Google Scholar

[5] P. H. D. Quoc and T. Uomoto, in: Proceeding of the 3rd ACF International Conference, ACF/VCA,Vietnam (2008), p.585

Google Scholar

[6] H.W. Reinhardt and T. Wüstholz: Materials and Structures 39 (2006), p.683

Google Scholar

[7] H. Hoornahad, E. Koenders and K. van Breugel: Key Engineering Materials Journal Vols. 417- 418 (2010), p.449

DOI: 10.4028/www.scientific.net/kem.417-418.449

Google Scholar

[8] H. Hoornahad, E. Koenders and K. van Breugel: Key Engineering Materials Journal Vols. 452- 453 (2011), p.569

DOI: 10.4028/www.scientific.net/kem.452-453.569

Google Scholar

[9] EN-12350-5: Testing Fresh Concrete-Part 5: Flow Table Test (2009)

Google Scholar

[10] Itasca Consulting Group Inc: Theory and Background. PFC2D, USA, (2008)

Google Scholar

[11] H. Hoornahad and E. Koenders: Advanced Materials Research Vols. 295-297 (2011), p.2171

Google Scholar

[12] F. Radjai, J. Schäfer, S. Dippel and D. Wolf: J.Phys. I France 7 (1997), p.1053

Google Scholar

[13] L. Brendel and S. Dippel in: Physics of Dry Granular Media, Edited by H. J. Herrmann, J.-P. Hovi and S. Luding, Kluwer Academic Publishers, Dordrecht (1998), p.313

Google Scholar