ebook img

Non-Linear Mechanics of Reinforced Concrete PDF

768 Pages·2003·43.204 MB·English
Save to my drive
Quick download
Download
Most books are stored in the elastic cloud where traffic is expensive. For this reason, we have a limit on daily download.

Preview Non-Linear Mechanics of Reinforced Concrete

Nonlinear Mechanics of Reinforced Concrete “fm” — 2003/2/20 — page i — #1 This page intentionally left blank “fm” — 2003/2/20 — page ii — #2 Nonlinear Mechanics of Reinforced Concrete K. Maekawa, A. Pimanmas and H. Okamura “fm” — 2003/2/20 — page iii — #3 Firstpublished2003 bySponPress 11NewFetterLane,LondonEC4P4EE SimultaneouslypublishedintheUSAandCanada bySponPress 29West35thStreet,NewYork,NY10001 This edition published in the Taylor & Francis e-Library, 2004. Spon Press is an imprint of the Taylor & Francis Group ©2003K.Maekawa,A.PimanmasandH.Okamura Allrightsreserved.Nopartofthisbookmaybereprintedorreproducedor utilisedinanyformorbyanyelectronic,mechanical,orothermeans,now knownorhereafterinvented,includingphotocopyingandrecording,orin anyinformationstorageorretrievalsystem,withoutpermissioninwriting fromthepublishers. BritishLibraryCataloguinginPublicationData AcataloguerecordforthisbookisavailablefromtheBritishLibrary LibraryofCongressCataloginginPublicationData Maekawa,Koichi,1938– Nonlinearmechanicsofreinforcedconcrete/K.Maekawa,A.Pimanmas, andH.Okamura. p.cm. Includesbibliographicalreferencesandindex. 1.Reinforcedconcreteconstruction.2.Reinforcedconcrete–Mathematicalmodels. 3.Nonlinearmechanics.I.Pimanmas,A.(Amorn)II.Okamura,Hajime,1938–III.Title. TA683.2.M3452003 (cid:1) 624.1 8341–dc21 2002030206 ISBN 0-203-30288-5 Master e-book ISBN ISBN 0-203-34659-9 (Adobe eReader Format) ISBN0–415–27126–6(alk.paper) “fm” — 2003/2/20 — page iv — #4 Contents List of figures xvii List of tables xxxvii Preface xxxix Acknowledgments xliii PART 1 Analysis and modeling of reinforced concrete 1 1 Introduction 3 1.1 Behavioral simulation of structures 3 1.1.1 Constitutive modeling: how to represent the nonlinear mechanics of reinforced concrete? 3 1.1.2 Nonlinear structural analysis: how to use nonlinear mechanics? 4 1.1.3 Verification of nonlinear modeling: applicability and reliability? 6 1.2 Engineering applications 6 1.2.1 Performance-based design 6 1.2.2 Limit state criteria 9 1.2.3 Performance assessment of existing structures 11 1.3 Organization of the book 12 References 12 2 Two-dimensional analysis of reinforced concrete 13 2.1 The concept of smeared cracks: a space-averaged constitutive model 13 2.2 Direction of cracking 15 2.3 Implicit formulation: preliminary discussion 17 2.4 Explicit formulation: the active crack approach 18 “fm” — 2003/2/20 — page v — #5 vi Contents 2.5 The orthogonal two-way fixed crack model 20 2.5.1 The concrete model before cracking 21 2.5.2 The cracked concrete model 24 2.6 The quasi-orthogonal two-way fixed crack approach 44 2.7 Verification of the two-way fixed crack model 45 2.7.1 Shear panels subjected to monotonic loads 46 2.7.2 Shear panels subjected to reversed cyclic loading 49 2.7.3 The SE-series panel tested by Stevens et al. 53 2.8 Four-way fixed crack model 54 2.8.1 Basic concept 54 2.8.2 Strategic framework 55 2.9 Verification of the four-way fixed crack model 61 2.9.1 The average shear stress–average shear strain relation 67 2.9.2 The average shear stress–normal strain relation 68 2.9.3 Crack angles 68 2.10 Two-dimensional structural analysis 68 2.10.1 Shear walls 69 2.10.2 Shear failure of RC members 74 2.10.3 A five-storied shear wall subjected to dynamic loading 92 2.10.4 Analysis of scaled-down test structures 94 2.11 Shear failure of a high-strength concrete beam 101 2.11.1 Analytical method and constitutive models 102 2.11.2 Experimental verification 103 2.12 A shear wall subject to horizontal two-directional loading 112 2.13 An underground box culvert 115 References 121 3 Three-dimensional analysis of reinforced concrete 125 3.1 General concept 125 3.2 An elasto-plastic and continuum-fracture model for uncracked concrete 126 3.2.1 The modeling concept 126 3.2.2 The elasto-plastic fracture model 126 3.2.3 A three-dimensional multi-directional smeared crack model 132 “fm” — 2003/2/20 — page vi — #6 Contents vii 3.3 A three-dimensional zoning concept and anisotropic post-cracking response 134 3.3.1 Anisotropic tension stiffening/softening behavior 136 3.3.2 Anisotropic shear fracture 140 3.3.3 Anisotropic average yield strength 141 3.4 Nonlinear structural analysis 144 3.4.1 An RC column subjected to unilateral loading 144 3.4.2 Torsion of plain and RC members 147 3.4.3 Multi-directional shear failure of a short RC column 156 3.4.4 Combined torsion and shear 162 3.4.5 RC columns under cyclic combined axial force, torsion and bending/shear 164 References 173 4 Nonlinear soil–structure interaction 176 4.1 The complete soil–structure system of nonlinearity 176 4.2 Modeling of soil and soil–RC interface 177 4.2.1 Modeling of soil and foundation 177 4.2.2 Soil–structure interface 183 4.2.3 Verification of the RC–soil system: a box culvert tested by the JSCE committee 185 4.3 Nonlinear static response of underground RC structures 188 4.3.1 Macro indicators 188 4.3.2 Limit state criterion 190 4.3.3 Shear response of the RC box culvert tested by the JSCE committee 191 4.3.4 Parametric study 192 4.4 A nonlinear dynamic analysis of the RC–soil system 195 4.4.1 Analysis method 195 4.4.2 Nonlinear dynamic response of an underground RC vertical duct 197 4.4.3 Nonlinear dynamic analysis of an underground multi-vent box culvert 200 4.5 The failure/collapse mechanism of damaged underground structures 209 4.5.1 Failure of underground RC culverts in an earthquake 209 viii Contents 4.5.2 Case study 1: Daikai station 210 4.5.3 Case study 2: Kamisawa station 215 References 223 5 Three-dimensional analysis of shells and frames 225 Part 1: Shell elements 225 5.1 Introduction 225 5.2 Degenerated shell elements and layered formulations 226 5.3 Geometrical nonlinearity 231 5.4 Integration scheme 232 5.5 Crack patterns in a shell element subjected to out-of-plane transverse loads 233 5.6 Verification of shell element 234 5.6.1 Shell elements under combined out-of-plane flexure and in-plane forces 234 5.6.2 A shell element subjected to combined transverse shear and in-plane forces 235 5.6.3 Slabs under cyclic transverse loading 239 5.6.4 A box culvert under cyclic loading 243 5.6.5 An RC cylindrical tank subject to reversed cyclic loading 244 Part 2: Frame elements 248 5.7 Fiber formulation 248 5.7.1 Degeneration of fields 248 5.7.2 Normal stress, stiffness and fiber assembly 252 5.7.3 Shear stress and the stiffness model 256 5.7.4 Geometrical nonlinearity in a frame element 258 5.7.5 Constitutive modeling and RC zoning 259 5.8 Verification of frame elements 260 5.8.1 Interaction diagram of a column 260 5.8.2 Cyclic loading of a steel tube 260 5.8.3 Cyclic loading of an RC square box-section 261 5.8.4 Three-dimensional cyclic loading of a concrete-filled tube sub-assemblage 263 5.8.5 Multi-directional flexure subject to eccentric axial forces 264 5.8.6 Three-dimensional dynamic analysis of a multi-story frame 275 5.9 Buckling and spalling models 276 5.9.1 The compression envelope of reinforcement and cyclic loops 276 5.9.2 Cover concrete spalling 279 “fm” — 2003/2/20 — page viii — #8 Contents ix 5.9.3 Mesh size consistency 280 5.9.4 Giuffre–Menegotto–Pinto model for cyclic loops 281 5.10 Frame members under large lateral deformation 283 5.10.1 An RC column subjected to reversed cyclic load 283 5.10.2 A high-strength composite RC column subjected to reversed cyclic load 286 5.10.3 Dynamic analysis of an RC pier 288 5.11 Post-peak cyclic response analysis 288 5.11.1 Experimental set-up and specimen details 289 5.11.2 Numerical simulation of the experiments 291 5.12 Geometrical nonlinearity in the collapse of RC piers 294 References 296 6 Analysis of strengthened and retrofitted structures 300 6.1 Background 300 6.2 A structural steel model 300 6.2.1 Elasto-perfectly plastic plane stress routine 301 6.2.2 Parallel elasto-plastic model 304 6.2.3 Verification of constitutive modeling 306 6.3 A carbon fiber sheet model 308 6.4 A steel–concrete interface model 309 6.4.1 Requirement of modeling 309 6.4.2 A softening plasticity interface model 309 6.4.3 Numerical integration 314 6.4.4 Verification: uniform stress field 315 6.5 Concentric and eccentric compression of strengthened columns 319 6.5.1 The effect of steel–concrete shear transfer mechanisms 319 6.5.2 Carbon fiber sheet as confining agents 323 6.5.3 Carbon fiber sheets versus steel jackets 327 6.5.4 Eccentric compression 330 6.6 RC columns strengthened by steel encasement 331 6.6.1 Practical needs 331 6.6.2 Consideration of discontinuities in analysis 332 6.6.3 Overall response 334 6.7 RC columns strengthened by carbon fiber sheet wrapping 335 6.7.1 Strengthening of RC columns failing in flexure 335 “fm” — 2003/2/20 — page ix — #9

See more

The list of books you might like

Most books are stored in the elastic cloud where traffic is expensive. For this reason, we have a limit on daily download.