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Abstract

Multiple detonations might occur in both accidental explosions and terrorism attacks. Generally, normal reinforced concrete (RC) structures which are not designed to withstand high intensity blast loads are not capable of withstanding explosions from a single blast let alone a sequence of more than one blast. Since concrete is often highly cracked and damaged from the first blast, the remaining deteriorated concrete and steel reinforcement in a RC member becomes very vulnerable to collapse. This paper reports on the feasibility of using fibre reinforced polymer (FRP) to strengthen a normal RC slab capable of sustaining two independent air blasts. Apart from the experimental investigation, numerical studies have been conducted to verify the concrete and FRP material models when they are utilized to predict the behaviour of FRP-RC structures under multiple blasts. This article provides guidance on how to choose appropriately between the two existing concrete models available in the LS-DYNA code.

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References

Crawford

J.E.

Malvar

L.J.

Wesevich

J.W.

Valancius

and Raynolds

A.D.

, Retrofit of reinforced concrete structures to resist blast effects, ACI Structural Journal, 1997, 94(4), 371–377.

Mosalam

K.M.

and Mosallam

A.S.

, Nonlinear transient analysis of reinforced concrete slabs subjected to blast loading and retrofitted with CFRP composites, Composite Part B: Engineering, 2001, 32(8), 623–636.

Tolba

, Response of FRP-retrofitted reinforced concrete panels to blast loading, Ph.D. Thesis, Carleton University, 2001.

Silva

P.F.

and Lu

, Improving the blast resistance capacity of RC slabs with innovative composite materials, Composites Part B: Engineering, 2007, 38(5–6), 523–534.

Oehlers

D.J.

Wachl

Glynn

Spencer

Merrigan

and Day

, Blast testing of RC slabs retrofitted with NSM CFRP plates, Advances in Structural Engineering, 2007, 10(4), 397–414.

Ohkubo

Beppu

Ohno

and Satoh

, Experimental study on the effectiveness of fiber sheet reinforcement on the explosive-resistant performance of concrete plates, International Journal of Impact Engineering, 2008, 35(12), 1702–1708.

Oehlers

D.J.

Rebentrost

Leach

and Whittaker

A.S.

, Blast testing of ultra-high performance fibre and FRP-retrofitted concrete slabs, Engineering Structures, 2009, 31(9), 2060–2069.

Jones

Oehlers

D.J.

Whittaker

A.S.

Sun

Marks

and Coppola

, Finite difference analysis of simply supported RC slabs for blast loadings, Engineering Structures, 2009, 31(12), 2825–2832.

Livermore Software Technology Corporation (LSTC), LS-DYNA version 971 keyword user's manual, 2007.

10.

Comité Euro-International du Béton – Fédération Internationale de la Précontrainte, CEB-FIP Model Code 90, 1990.

11.

Broadhouse

B.J.

, The Winfrith concrete model in LS-DYNA3D, 1995.

12.

Malvar

L.J.

, Review of static and dynamic properties of steel reinforcing bars, ACI Materials Journal, 1998, 95(5), 609–616.

13.

Tanapornraweekit

, Behaviour of fibre reinforced polymer (FRP) strengthened RC slabs subjected to blast loading, Ph.D. Thesis, University of Melbourne, 2010.

14.

Smith

P.D.

and Mays

G.C.

, Blast effects on buildings, Thomas Telford, London, 1995.

Finite Element Simulation of FRP Strengthened Reinforced Concrete Slabs under Two Independent Air Blasts

Abstract

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