TY - CHAP
T1 - Tensile fatigue response of sisal fiber reinforced cement composites
AU - Silva, Flávio de Andrade
AU - Mobasher, Barzin
AU - Toledo Filho, Romildo D.
N1 - Publisher Copyright: © 2009 Institute of Fundamental Technological Research, Warsaw.
PY - 2009/11/30
Y1 - 2009/11/30
N2 - Tensile fatigue behavior of composite materials are of significant interest since in structural applications they are often subjected to cyclic loading. However, very few results for fiber reinforced concrete under cyclic load have been reported. In the present research sustainable cement composites were produced by partially replacing 50% of Portland cement with calcined clays and using natural sisal fibers as reinforcement. These composites presented ultimate monotonic tensile stress of 12MPa and strain at failure of up to 1.5%. Tension-tension fatigue tests were performed with maximum stress levels ranging from 4 to 9.6MPa at a frequency of 2Hz. These tests were carried out up to 106 cycles or until the composite failure, whichever occurred first. It was found that up to 6MPa the composites were able to survive 106 cycles. Composites that survived 106 cycles were re-tested under monotonic load to establish its residual strength. Optical fluorescent microscopy was used to observe the cracking mechanisms after fatigue tests.
AB - Tensile fatigue behavior of composite materials are of significant interest since in structural applications they are often subjected to cyclic loading. However, very few results for fiber reinforced concrete under cyclic load have been reported. In the present research sustainable cement composites were produced by partially replacing 50% of Portland cement with calcined clays and using natural sisal fibers as reinforcement. These composites presented ultimate monotonic tensile stress of 12MPa and strain at failure of up to 1.5%. Tension-tension fatigue tests were performed with maximum stress levels ranging from 4 to 9.6MPa at a frequency of 2Hz. These tests were carried out up to 106 cycles or until the composite failure, whichever occurred first. It was found that up to 6MPa the composites were able to survive 106 cycles. Composites that survived 106 cycles were re-tested under monotonic load to establish its residual strength. Optical fluorescent microscopy was used to observe the cracking mechanisms after fatigue tests.
KW - Cementitious composites
KW - Fatigue
KW - Sisal fiber
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U2 - 10.1533/9781845697754.81
DO - 10.1533/9781845697754.81
M3 - Chapter
SN - 9781845697754
T3 - Brittle Matrix Composites 9, BMC 2009
SP - 81
EP - 90
BT - Brittle Matrix Composites 9
PB - Elsevier
T2 - 9th International Symposium on Brittle Matrix Composites, BMC 2009
Y2 - 25 October 2009 through 28 October 2009
ER -