Tensile behavior of strain-hardening geopolymer composites (SHGC) under impact loading

Tensile behavior of strain-hardening geopolymer composites (SHGC) under impact loading

Strain-hardening geopolymer composites (SHGC) exhibit remarkable ductility, crack control and high energy dissipation capacity when subject to quasi-static tensile loading. However, their mechanical performance under dynamic loading has not yet been explored. A comprehensive assessment of possible r...

Full description

Saved in:
Bibliographic Details
Published in:Cement & concrete composites Vol. 113; p. 103703
Main Authors: Trindade, Ana Carolina Constâncio, Heravi, Ali A., Curosu, Iurie, Liebscher, Marco, de Andrade Silva, Flávio, Mechtcherine, Viktor
Format: Journal Article
Language:English
Published: Elsevier Ltd 01-10-2020
Subjects:
Fiber reinforcement
Geopolymer composite
Impact
PVA
Split-Hopkinson tension bar
UHMWPE
Impact
PVA
Split-Hopkinson tension bar
UHMWPE
Geopolymer composite
Fiber reinforcement
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Strain-hardening geopolymer composites (SHGC) exhibit remarkable ductility, crack control and high energy dissipation capacity when subject to quasi-static tensile loading. However, their mechanical performance under dynamic loading has not yet been explored. A comprehensive assessment of possible rate effects is required to facilitate a targeted material design for various practical applications. The article presents the results of an experimental investigation on the mechanical behavior of two types of SHGC under both quasi-static and impact tensile loading. The composites were reinforced with 2% of either short polyvinyl alcohol (PVA) fiber or ultra-high molecular-weight polyethylene (UHMWPE) fiber. The experiments were performed both at the composite scale and at the fiber level. The impact tests on the plain geopolymer matrix and SHGC were performed in a gravity-driven split-Hopkinson tension bar (SHTB) at strain rates of up to 300 s−1. The tests were accompanied by optical measurements to assess specimen deformation and multiple cracking by means of Digital Image Correlation (DIC). The dynamic fiber-matrix bond properties were investigated in a miniature split Hopkinson bar. Both under quasi-static tensile loading and impact tensile loading, the SHGC made with UHMWPE fibers exhibited superior mechanical performance compared to the composite made with PVA fibers. When comparing the impact tensile performance of SHGC with normal-strength SHCC from previous studies, SHGC demonstrated higher dynamic tensile strength and energy dissipation capacity, making SHGC promising for strengthening/prospective applications against highly dynamic actions.
ISSN:0958-9465
1873-393X
DOI:10.1016/j.cemconcomp.2020.103703