Performance of soft-hard-soft (SHS) cement based composite subjected to blast loading with consideration of interface properties

Jun WU; Xuemei LIU

doi:10.1007/s11709-015-0301-2

Front. Struct. Civ. Eng. ›› 2015, Vol. 9 ›› Issue (3) : 323 -340. DOI: 10.1007/s11709-015-0301-2

RESEARCH ARTICLE

Performance of soft-hard-soft (SHS) cement based composite subjected to blast loading with consideration of interface properties

Jun WU ¹^,²
, Xuemei LIU ^*

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Abstract

This paper presents a combined experimental and numerical study on the damage and performance of a soft-hard-soft (SHS) multi-layer cement based composite subjected to blast loading which can be used for protective structures and infrastructures to resist extreme loadings, and the composite consists of three layers of construction materials including asphalt concrete (AC) on the top, high strength concrete (HSC) in the middle, and engineered cementitious composites (ECC) at the bottom. To better characterize the material properties under dynamic loading, interface properties of the composite were investigated through direct shear test and also used to validate the interface model. Strain rate effects of the asphalt concrete were also studied and both compressive and tensile dynamic increase factor (DIF) curves were improved based on split Hopkinson pressure bar (SHPB) test. A full-scale field blast test investigated the blast behavior of the composite materials. The numerical model was established by taking into account the strain rate effect of all concrete materials. Furthermore, the interface properties were also considered into the model. The numerical simulation using nonlinear finite element software LS-DYNA agrees closely with the experimental data. Both the numerical and field blast test indicated that the SHS composite exhibited high resistance against blast loading.

Keywords

high strength concrete (SHS) / engineered cementitious composite / interface / blast test / strain rate effect

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Jun WU, Xuemei LIU. Performance of soft-hard-soft (SHS) cement based composite subjected to blast loading with consideration of interface properties. Front. Struct. Civ. Eng., 2015, 9(3): 323-340 DOI:10.1007/s11709-015-0301-2

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References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Wu J. Development of advanced pavement materials system for blast load. Dissertation for the Doctoral Degree. Singapore: National University of Singapore, 2012

[2]	Zhang M H, Shim V P W, Lu G, Chew C W. Resistance of high-strength concrete to projectile impact. International Journal of Impact Engineering, 2005, 31(7): 825–841

[3]	Zhang M H, Sharif M S H, Lu G. Impact resistance of high strength fibre-reinforced concrete. Magaine of Concrete Research, 2007, 199–210

[4]	Dancygier A N, Yankelevsky D Z. High strength concrete response to hard projectile impact. International Journal of Impact Engineering, 1996, 18(6): 583–599

[5]	Li V C, Maalej M. Toughening in cement based composites-Part II: Fiber-reinforced cementitious composites. Journal of Cement and Concrete Composites., 1996, 18(4): 239–249

[6]	Li V C, Mishra D K, Naaman A E, Wight J K, LaFave J M, Wu H C, Inada Y. On the shear behavior of engineered cementitious composites. Journal of Advanced Cement Based Materials, 1994, 1(3): 142–149

[7]	Koerner R M. Designing with Geosynthetics. N J: Prentice-Hall Eaglewood, 1998

[8]	LSDYNA. LSDYNA Keyword User’s Manual: Livermore Software Technology Corporation (LSTC), 2007

[9]	Riedel W, Kawai N, Kondo K. Numerical assessment for impact strength measurements in concrete materials. International Journal of Impact Engineering, 2009, 36(2): 283–293

[10]	Malvar L J, Crawford J E, Wesevich J W, Simons D. A plasticity concrete material model for DYNA3D. International Journal of Impact Engineering, 1997, 19(9−10): 847–873

[11]	Polanco-Loria M, Hopperstad O S, Borvik T, Berstad T. Numercial predictions of ballistic limit for concrete slabs using a modified version of the HJC concrete model. International Journal of Impact Engineering, 2008, 35(5): 290–303

[12]	Holmquist T J, Johnson G R, Cook W H. A computational constitutive model for concrete subjected to large strains, high strain rates, and high pressures. In: Proceedings of the 14th International Symposium on Ballistics. Quebec, Canada, 1993, 591–600

[13]	Chen W F. Constitutive Equations for Engineering Materials. John Wiley & Sons, 1982

[14]	Park D W, Martin T, Lee H S, Masad E. Characterization of permanent deformation of an asphalt mixture using a mechanistic approach. KSCE Journal of Civil Engineering, 2005, 9(3): 213–218

[15]	Tang W H, Ding Y Q, Yuan X Y. The HJC Model Parameters of an Asphalt Mixture. DYMAT 2009- 9th International Conference on the Mechanical and Physical Behaviour of Materials under Dynamic Loading, 2009, 1419–1423

[16]	Malvar L J, Crawford J E, Wesevich J W. A New Concrete Material Model for DYNA3D Release II: Shear Dilation and Directional Rate Enhancements. Defense Nuclear Agency: Alexandria, VA, USA, 1996

[17]	Karihaloo B L, Nallathambi P. Effective crack model for the determination of fracture toughness (Kice) of concrete. Engineering Fracture Mechanics, 1990, 35(4−5): 637–645

[18]	Tekalur S A, Shukla A, Sadd M, Lee K W. Mechanical characterization of a bituminous mix under quasi-static and high-strain rate loading. Construction & Building Materials, 2009, 23(5): 1795–1802

[19]	Magallanes J M, Wu Y, Malvar L J, Crawford J E. Recent improvements to release III of the K&C concrete model. In: Proceedings of the 11th International LSDYNA Users Conference. Detroit, USA, 2010, 37–48

[20]	Comite Euro-International du Beton. CEP-FIP Model Code 1990. Redwood Books, Trowbridge, Wiltshire, UK, 1993

[21]	Lee S C. Finite element modeling of hybrid-fiber ECC targets subjected to impact and blast. Dissertation for the Doctoral Degree. Singapore: National University of Singapore, 2006

[22]	Maalej M, Quek S T, Zhang J. Behavior of hybrid-fiber engineered cementitious composites subjected to dynamic tensile loading and projectile impact. Journal of Materials in Civil Engineering, 2005, 17(2): 143–152

[23]	Lee K Z Z, Chang N Y, Ko H Y. Numerical simulation of geosynthetic-refinforced soil wall under seismic shaking. Geotextiles and Geomembranes, 2010, 28(4): 317–334

[24]	Wang F, Lim C H, Soh T B. Explosive testing, numerical and analytical modelling of a modular blast wall system. In: Proceedings of the 3rd International Conference on Design and Analysis of Protective Structures. Singapore, 2010, 392–401

[25]	Hyde D. ConWep-Application of TM5−855−1. Fundamentals of protective design for conventional weapons. Vicksburg, MS: Structural Mechanics Division, Structures Laboratory, USACE Waterways Experiment Station, 1992

[26]	Wu J, Chew S H. Field performance and numerical modelling of multi-layer pavement system subject to blast load. Construction & Building Materials, 2014, 52: 177–188