Low cycle fatigue life of high-strength reinforcing steel bars (ASTM A706 Grade 80), using photogrammetry by RGB
methodology is evaluated. Fatigue tests are performed on specimens under constant axial displacement with total
strain amplitudes ranging from 0.01 to 0.05. The experimental observations indicate that buckling of high-strength
reinforcing bars results in a damaging degradation of their fatigue life performance as the slenderness ratio increases,
including an early rebar failure as the total strain amplitude increases since it achieves the plastic range faster. In
addition to this, the results show that the ratio of the ultimate tensile strength to yield strength satisfies the minimum
of 1.25 specified in ASTM A706 for reinforcement. On the other hand, the RGB methodology indicates that the
axial strains measured by photogrammetry provide more accurate data since the registered results by the traditional
experimental setup do not detect second-order effects, such as slippage or lengthening of the specimens within the
clamps. Moreover, the RGB filter is faster than digital image correlation (DIC) because the RGB methodology requires a
fewer computational cost than DIC algorithms. The RGB methodology allows to reduce the total strain amplitude up
to 45% compared to the results obtained by the traditional setup. Finally, models relating total strain amplitude with
half-cycles to failure and total strain amplitude with total energy dissipated for multiple slenderness ratios (L/d of 5, 10,
and 15) are obtained.
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Lenguage
dc.language.iso
en
es_ES
Publisher
dc.publisher
Springer
es_ES
Type of license
dc.rights
Attribution-NonCommercial-NoDerivs 3.0 United States