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A New Procedure for Mode I Fracture Characterization of Cement‐Based Materials
Author(s) -
Dourado N.,
Moura M. F. S. F.,
Xavier J.,
Pereira F. A. M.
Publication year - 2015
Publication title -
strain
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.477
H-Index - 47
eISSN - 1475-1305
pISSN - 0039-2103
DOI - 10.1111/str.12165
Subject(s) - materials science , fracture toughness , structural engineering , displacement (psychology) , fracture (geology) , beam (structure) , finite element method , bending , digital image correlation , bilinear interpolation , composite material , stress (linguistics) , fracture mechanics , enhanced data rates for gsm evolution , three point flexural test , mathematics , computer science , engineering , psychology , telecommunications , linguistics , philosophy , psychotherapist , statistics
Abstract Fracture characterization under mode I loading of a cement‐based material using the single‐edge‐notched beam loaded in tree‐point‐bending was performed. A new method based on beam theory and crack equivalent concept is proposed to evaluate the Resistance ‐curve, which is essential to determine fracture toughness with accuracy. The method considers the existence of a stress relief region in the vicinity of the crack, dispensing crack length monitoring during experiments. A numerical validation was performed by finite element analysis considering a bilinear cohesive damage model. Experimental tests were performed in order to validate the numerical procedure. Digital image correlation technique was used to measure the specimen displacement with accuracy and without interference. Excellent agreement between numerical and experimental load–displacement curves was obtained, which validates the procedure.