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2015 Vol.28, Issue 5 Preview Page
An Evaluation of Blast Resistance of Partially Reinforced CFT Columns using Computational Analysis

전산해석을 이용한 부분 보강된 CFT 기둥의 폭발저항성능 평가

Kim Han-Soo*
,
Wee Hae-Hwan
Division of Architecture
Department of Architectural Engineering

• 본 논문에 대한 토의를 2015년 10월 30일까지 학회로 보내주시면 2015년 12월호에 토론결과를 게재하겠습니다.

*Corresponding Author : aaa
2015. pp. 503-510
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Abstract

본 논문에서는 부분 보강된 CFT 기둥의 폭발저항성능을 일반 CFT 기둥과 비교하여 강판 보강의 효과를 확인하였다. 폭발하중을 받는 CFT 기둥의 구조해석에는 폭발과 충돌 해석을 위한 특수한 하이드로코드인 Autodyn을 사용하여 수치해석을 수행하였다. 콘크리트와 이를 둘러싸고 있는 강판 사이의 상호작용을 모델링하는 여러 방법이 있다. 본 연구에서는 기둥의 실제 파괴를 표현하기 위해 마찰 옵션 및 조인 옵션으로 모델링하였다. 해석에 따르면, 부분 보강된 CFT 기둥은 일반 CFT 기둥에 비해 더 나은 폭발저항효과를 나타내었다. 보강 CFT기둥의 폭발저항성능은 콘크리트를 둘러싸고 있는 부분 보강된 강판의 높이가 높을수록 향상되었으며 CFT 기둥의 단면 크기 이상으로 보강할 것을 추천한다.

In this paper, the blast resisting performance of partially reinforced CFT columns was compared with the normal CFT columns to evaluate the effect of reinforcing with steel plates. Autodyn which is a specialized hydro-code for analysis of explosion and impact was used to simulate the structural behavior of the CFT columns under the blast loadings. The interaction between concrete and surrounding steel plates was modeled with friction and join option to represent the realistic damage of columns. According to the analysis, the partially reinforced CFT column showed enhanced blast resisting performance than the normal CFT columns. Also the improvement of blast resisting performance was depended on the height of reinforcing steel plates.

키워드
CFT 기둥, 폭발하중, 오토딘, 부분 보강
CFT column, blast load, autodyn, partially reinforcement
References
1
Ansys2005AUTODYN Theory ManualCentury Dynamics235
2
Bao, X., Li, B. 2010Residual Strength of Blast Damaged Reinforced Concrete ColumnsInt. J. Impact Eng.37295308510.1016/j.ijimpeng.2009.04.003
3
Chopra, A.K. 1995Dynamics of Structures (Theory and Applications to Earthquake Engineering)Prentice Hall,876
4
Cho, M., Parmerter, R.R.1992An Efficient Higher Order Plate Theory for Laminated CompositesCompos. Struct.20113123510.1016/0263-8223(92)90067-M
5
Cormie, D., Mays, G., Smith, P. 2009Blast Effects on Buildings 2nd editionThomas telfordUK338
10.1680/beob2e.35218
6
DoD2010Design of Buildings to Resist Progressive CollapseU.S Department of Defense.
7
Fujikura, S., Bruneau, M., Lopez-Garica, D.2008Experimental Investigation of Multihazard Resistant Bridge Piers Having Concrete-Filled Steel Tube under Blast LoadingJ .Bridge Eng.13586594510.1061/(ASCE)1084-0702(2008)13:6(586)
10.1061/(ASCE)1084-0702(2008)13:6(586)
8
GSA2003Progressive Collapse Analysis and Design Guidelines for New Federal Office Buildings and Major ModernizationU.S General Services Administration.
9
Ju, Y.T. 2005Progressive Finite Element Analysis of Steel-Concrete Interface Behaviors with Two Phase Failure Mechanisms of Bond and Shear SlipDoctoral thesisKonkuk University123
10
Kim, H.S., Park, J.P.2010An Evaluation of Blast Resistance Performance of RC Columns According to the Shape of Cross SectionJ. Comput. Struct. Eng. Inst. Korea234387394
11
Kim, H.S., Park, J.P. 2011Evaluation of Blast Resistance Performance for CFT Columns by Using Computational AnalysisJ. Archit. Inst, Korea Struct. & Constr.2736572
12
Kim, H.S., Ahn, H.S. 2014Erosion Criteria for the Progressive Collapse Analysis of Reinforcement Concrete Structure due to Blast Load J. Korea Concr. Inst263335342
10.4334/JKCI.2014.26.3.335
13
Lee, T. 2008Interface Behavior of Concrete Infilled Steel Tube Subjected to Flexure, Doctoral thesisKonkuk University137
14
Magnusson, J., Hansson, H. 2005Numerical Simulations of Concrete Beams-A Principal StudyNational Defence Research EstablishmentSweden63
15
Mutalib, A., Hao, H. 2011Development of P-I Diagrams for FRP Strengthed RC ColumnsInt. J. Impact Eng.38290304510.1016/j.ijimpeng.2010.10.029
16
Nyström, U., Gylltoft, K.2009Numerical Studies of The Combined Effects of Blast and Fragment LoadingInternational Journal of Impact Engineering69951005510.1016/j.ijimpeng.2009.02.008
17
Shi, Y., Hao, H., Li, Z. 2008Numerical Derivation of Pressure-Impulse Diagrams for Prediction of RC Column Damage to Blast LoadsInt. J. Impact Eng.3512131227510.1016/j.ijimpeng.2007.09.001
18
Smith, P.D., Hetherington, J.G. 1994Blast and Ballistic Loading of StructureLaxton's, Great Britain336
19
Wood, B.W. 2008Experimental Validation of an Integrated FRP and Visco-Elastic HardeningDamping and Wave-Modulating System for Blast Resistance Enhancement of RC Columns116
20
Wu, K., Li, B., Tsai, K. 2011Residual Axial Compression Capacity of Localized Blast-Damaged RC Columns Int. J. Impact Eng.3829402 510.1016/j.ijimpeng.2010.09.00
21
Zukas, J.A. 2004Introduction to HydrocodesElsevierUK313
Information
  • Publisher :Computational Structural Engineering Institute of Korea
  • Publisher(Ko) :한국전산구조공학회
  • Journal Title :Journal of the Computational Structural Engineering Institute of Korea
  • Journal Title(Ko) :한국전산구조공학회 논문집
  • Volume : 28
  • No :5
  • Pages :503-510
  • Received Date : 2015-05-11
  • Revised Date : 2015-06-17
  • Accepted Date : 2015-07-03
  • DOI :https://doi.org/10.7734/COSEIK.2015.28.5.503
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