High Performance Fiber Reinforced Cement Composites 6

High Performance Fiber Reinforced Cement Composites (HPFRCC) represent a class of cement composites whose stress-strain response in tension undergoes strain hardening behaviour accompanied by multiple cracking, leading to a high strain prior to failure. The primary objective of this International Workshop was to provide a compendium of up-to-date information on the most recent developments and research advances in the field of High Performance Fiber Reinforced Cement Composites. Approximately 65 contributions from leading world experts are assembled in these proceedings and provide an authoritative perspective on the subject. Special topics include fresh and hardening state properties; self-compacting mixtures; mechanical behavior under compressive, tensile, and shear loading; structural applications; impact, earthquake and fire resistance; durability issues; ultra-high performance fiber reinforced concrete; and textile reinforced concrete.

Target readers: graduate students, researchers, fiber producers, design engineers, material scientists.

Texte du rabat

High Performance Fiber Reinforced Cement Composites (HPFRCC) represent a class of cement composites whose stress-strain response in tension undergoes strain hardening behaviour accompanied by multiple cracking, leading to a high strain prior to failure. The primary objective of this International Workshop was to provide a compendium of up-to-date information on the most recent developments and research advances in the field of High Performance Fiber Reinforced Cement Composites. Approximately 65 contributions from leading world experts are assembled in these proceedings and provide an authoritative perspective on the subject. Special topics include fresh and hardening state properties; self-compacting mixtures; mechanical behavior under compressive, tensile, and shear loading; structural applications; impact, earthquake and fire resistance; durability issues; ultra-high performance fiber reinforced concrete; and textile reinforced concrete.

Target readers: graduate students, researchers, fiber producers, design engineers, material scientists.

Contenu

Dedication.- Preface.- Workshop.- Acknowledgements.- Part 1: Composite properties in the fresh and hardened states;1 Strength dependent tensile behavior of strain hardening fiber reinforced concrete, by D.J. Kim, K. Wille, A.E. Naaman, S. El-Tawil.- 2 Tailoring SHCC made of steel cords and plastic fibers, by A. P. Fantilli, H. Mihashi, T. Naganuma, T. Nishiwaki.- 3 Model of hooked steel fibers reinforced concrete under tension, by C. Sujivorakul.- 4 Use of double punch test to evaluate the mechanical performance of fiber reinforced concrete, by S.-H. Chao, N. Karki, J.-S. Cho, R. Waweru.- 5 Determining specimen size influences on FRC response using the digital image correlation technique, by L.N. Talboys, A.S. Lubell, V.S. Bindiganavile.- 6 Connecting non-destructive fiber dispersion measurements with tensile HPFRCC behavior, by L. Ferrara, M. Faifer, M. Muhaxheri, S. Toscani,R. Ottoboni.- 7 Improved tensile performance with fiber reinforced self-compacting concrete, by S. Grünewald, F. Laranjeira, J. Walraven, A. Aguado,C. Molins.- 8 The impact of rheology on the mechanical performanceof steel fiber reinforced concrete, by G.P.A.G. van Zijl, S. Zeranka.- 9 Quantification of fresh and mechanical properties of HFRCC by excess paste thickness, by H. Mihashi, N. Ishikawa.- 10 An investigation of mechanical properties of jute fiber-reinforced concrete, by J. Kim, C. Park, Y. Choi, H. Lee, G. Song.- 11 Back-calculation of tensile properties of strain softening and hardening cement composites, by M. Bakhshi, C. Barsby, B. Mobasher.- 12 Basis of a finite-element simulation tool to predict the flexural behavior of SFRC prisms,by T. Soetens, S. Matthys, L. Taerwe, A. Van Gysel.- 13 Multifunctional carbon black engineered cementitious composites for the protection of critical infrastructure, by M. Li, V. Lin, J. Lynch, V.C. Li.- 14 Effects of fiber dispersion and flaw sizedistribution on the composite properties of PVA-ECC, by R. Ranade, M.D. Stults, B. Lee, V.C. Li.- Part 2: Bond and pull-out mechanisms.- 15 Groups of physical parameters influencing the three stages pull-out behavior of glass multi-filament yarns embedded in micro-concrete, by H. Aljewifi, B. Fiorio, J-L. Gallias.- 16 Tailor-made steel fiber reinforced ultra high performance concrete - single fiber pull-out, bending capacity and fracture toughness, by T. Stengel, X. Lin, P. Schießl, C. Gehlen.- 17 Study on size effect in bond splitting behavior of ECC, by K. Asano, T. Kanakubo.- 18 Experimental and nonlinear finite element analysis of fiber-cementitious matrix bond-slip mechanism, by C. S. Chin, R. Y. Xiao.- Part 3: Durability.- 19 Self-healing of engineered cementitious composites in the natural environment, by E. Herbert, V.C. Li.- 20 Resistance to corrosion induced cracking in self consolidating hybrid fiber reinforced concrete, by G. Jen, C.P. Ostertag.- 21 Basic creep under compression and direct tension loads of self-compacting-steel fibers reinforced concrete, by E. Marangon, R.D. Toledo Filho, E.M.R. Fairbairn.- 22 Hot and residual behavior of steel fiber-reinforced structural shotcrete exposed to high temperature, by P. Bamonte, P.G. Gambarova, A. Nafarieh.- Part 4: Structural elements: design, detailing, shear, tension stiffening.- 23 Optimization of HPFRCC-structures with innovative computational methods, by S. Grünewald, M. Flint, H. Han, J. Coenders, J.C. Walraven.- 24 Structural applications of hybrid fiber engineered cementitious composites - a review, by M. Maalej.- 25 D-zones in HPFRC, by M. Colombo, M. di Prisco.- 26 Effect of fiber reinforced concrete in members with highly complex stress fields, by S.-H. Chao, T. Pareek, D.R. Sahoo.- 27 Towards a design model for steel fiber reinforced concrete in bending, by G.P.A.G. vanZijl, P.B. Mbewe.- 28 Shear crack formation and propagation in fiber reinforced cementitious composites (FRCC), by I. Paegle, G. Fischer.- 29 Effects of shear transfer on the directions of principal strain field in cracked concrete with hooked steel fibers, by B. Suryanto, K. Nagai, K.Maekawa.- 30 Mechanical interaction between concrete and structural reinforcement in the tension stiffening process, by L. Larusson, G. Fischer, J. Jönsson.- 31 Confinement and tension stiffening effects in high performance self-consolidated hybrid fiber reinforced concrete composites, by W. Trono, G. Jen, D. Moreno, S. Billington, C.P. Ostertag.- 32 Tension-stiffening in reinforced high performance fiber-reinforced cement-based composites under direct tension, by D.M. Moreno, W. Trono, G. Jen, C. Ostertag, S.L. Billington.- 33 Crack formation in FRC structural elements containing conventional reinforcement, by J. Deluce, S.-C. Lee, F. Vecchio.- 34 Strength and behavior of SFRSCC and SFRC wall panels under one-way in-plane action, by N. Ganesan, P.V. Indira, S. Rajendra Prasad.- Part 5: Impact, cyclic and seismic loading.- 35 Drop-weight impact response of glass-fiber reinforced ceramic concrete, by S. Tassew, R. Mutsuddy, V.S. Bindiganavile, A.S. Lubell.- 36 Mechanical behavior of SHCC under impact loading, by V. Mechtcherine, O. Millon, M. Butler, K. Thoma.- 37 Shock-absorbing blocks made of HPFRCC for better girder-end structures, by K. Rokugo, H. Hatano, T. Nakashima, Y. Sakaguchi, M. Yamakami, K. Kobayashi.- 38 Post-peak cyclic behavior of steel fiber reinforced concrete under bending, by F. Germano, G. Plizzari.- 39 Seismic strengthening of piers by using high ductility cement, by K. Kosa, H. Shimizu, M. Kusano, H. Goda.- 40 Drift limits of concrete frame members reinforced with high-performance steel bars and fibersH. Tavallali, A. Lepage, J. Rautenberg, S. Pujol.- 41 Dynamic behavior of HPFRCC at high strain rate: the fiber role, by A. Caverzan, E. Cadoni, M. di Prisco.- 42Beam-column connections for precast concrete frames usi…