콘크리트학회논문집 (Journal of the Korea Concrete Institute)

  • 제12권1호
  • /
  • Pages.3-12
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  • 2000
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  • 1229-5515(pISSN)
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  • 2234-2842(eISSN)
한국콘크리트학회 (Korea Concrete Institute)
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콘크리트 파괴역학을 이용한 철근콘크리트 인장부재의 균열성장 해석

Cracking Analysis of Reinforced Concrete Tension Members with Concrete Fracture Mechanics

  • 홍창우 (강원대학교 산업기술연구소 연구원) ;
  • 윤경구 (강원대학교 토목공학과) ;
  • 양성철 (한국도로공사 도로연구소 책임연구원)
  • 발행 : 2000.02.01
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초록

A fracture energy concept proposed by Ouyang and Shah's fracture mechanics approach was used to predict cracking of reinforced concrete members subjected to tension. In this approach, fracture properties in plain concrete which incorporate the presence of the fracture process zone are first determined from the generalized size effect method, then fracture energy required for crack propagation with the same dimension and material properties are evaluated using an R-curve. Subsequently taking into account the material properties in Ouyang and Shah's approach, a theoretical analysis to predict the mechanical behavior of reinforced concrete members subjected to tension was performed and compared to observed experimental results. It is seen that the predicted average crack spacing curves agree well with the experimental results, whereas the analytical method seems to predict lower values for this study. The analytical approach predicts well responses of stress-strain curves before and after the first crack is formed. It is concluded from this study that a fracture energy concept based on the R-curve and the generalized size effect method is a rational approach to predict cracking of reinforced concrete members subjected to tension.

키워드

참고문헌

  1. 224.2R-92.ACI Manual of Concrete Practice Part3.Use of Concrete in Buildings-Design.Specifications.and Related Topics Cracking of concrete memvers in direct tension
  2. Journal of Structural Engineering.ASCE v.109 no.9 spacing of cracks in reinforced concrete Bazant,S.P.;Oh, B.
  3. ACI Structural Journal v.91 no.1 Fracture energy approach for predicting cracking of reinforced concrete tensile members Ouyang,C.;Shah,S.P.
  4. Journal of Structural Engineering v.110 no.6 Approximate linear analyses of concrete fracture by R-curves Bazant,Z.P.;Cedolin,L.
  5. Journal of Engineering Fracture Mechanics v.55 no.3 Variavle-notch one-size test method for fracture energy and process zone length Tang,T.;Bazant,Z.P.;Yang,S.;Zollinger,D.G.
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  7. Journal of the American Cermic Society v.74 no.11 Geometry dependent R-curve for quasi-brittle materials Ouyang,C.;Shah,S.P.
  8. International Journal of Fracture v.44 Determination of fracture energy process zone length and brittleness number form size effect with application to rock and cincrete Bazant,Z.P.;Kazemi.M.T.
  9. ASCE v.104 no.ST12 Tension stiffening in reinforced concrete slabs Gilbert,R.I.;Warner,R.F.
  10. Journal of the American Ceramin Society v.74 no.9 Characterization of interfacial properties in fiber reinforced cementitious composites Li,Z.;Mobasher,B.;Shsh,S.P.
  11. ACI Materials Journal v.89 no.3 Fracture process zone for concrete for dynamic loading Ku,J.;Yon.J.H.;Hawkins,N.M.;Arakawa,K.;Kobayashi,A.S.
  12. 강원대학교 박사학위논문 강섬유보강 고강도 철근콘크리트 부재의 인장강성모델 개발 및 비선형해석 홍창우