2016
DOI: 10.1016/j.istruc.2015.10.008
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Behavior of GFRP bridge deck panels infilled with polyurethane foam under various environmental exposure

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Cited by 25 publications
(9 citation statements)
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“…Many factors, such as temperature, irradiation, moisture, chemicals, and presence of an active physical stress, can significantly affect the durability of the polymeric material. 8,9 Increased temperature also causes considerable reductions in the shear modulus of GFRP composite, following a variation trend that is in general agreement with the corresponding DMA results, namely of the storage modulus. 10 Parallel identification of glass FRP bridge deck panel by differential thermal analysis, spectroscopy analysis, scanning and optical microscope monitoring, DMA and DSC analysis, tensile and flexural tests were presented in Zhu's and Lopez's work.…”
Section: Introductionsupporting
confidence: 86%
See 1 more Smart Citation
“…Many factors, such as temperature, irradiation, moisture, chemicals, and presence of an active physical stress, can significantly affect the durability of the polymeric material. 8,9 Increased temperature also causes considerable reductions in the shear modulus of GFRP composite, following a variation trend that is in general agreement with the corresponding DMA results, namely of the storage modulus. 10 Parallel identification of glass FRP bridge deck panel by differential thermal analysis, spectroscopy analysis, scanning and optical microscope monitoring, DMA and DSC analysis, tensile and flexural tests were presented in Zhu's and Lopez's work.…”
Section: Introductionsupporting
confidence: 86%
“…In spite of these disadvantageous conditions, the expected life time of the structure is minimum 100 years. The general view of the footbridge and its longitudinal section with the most important dimensions are shown in Figure 1 Specimens cut from commercial GFRP pultruded profiles, currently being used for infrastructure applications, were submitted to mainly four different exposure environments, in many researchers' investigations [2][3][4][5][6][7][8][9] for example: (1) immersion in water at 20 C, (2) condensation of water at 60 C, (3) artificial accelerated weathering in a QUV equipment, and (4) artificial accelerated weathering in a Xenon-arc equipment. After submitting the material to those aggressive environments, the behavior was analyzed, the tensile and flexural behaviors were studied, the chromatic and gloss variations were measured and the chemical changes were investigated by means of IR spectroscopy, in previous literature.…”
Section: Experimental Programmentioning
confidence: 99%
“…Researchers in past years have mainly focused on flexural behavior, buckling and stress concentration in these bridge decks panels. Tuwair et al studied the influence of different environmental factors on such PU core‐based deck panels. Sandwich panels were exposed to thermal cycling, ultraviolet radiation and deicing solution prior to flexural testing.…”
Section: Puf Core Sandwich Structuresmentioning
confidence: 99%
“…Foam-filled composites produced in batches for structural applications in the building sector present a higher variability in material properties than those manufactured in bulk and under tightly controlled curing conditions for applications such as shipping and aerospace. 34,35 Therefore, the temperature could produce a post-curing effect on the PU, leading to a higher homogeneity between specimens. The post-curing would increase the number of links in the polymer matrix, which is consistent with the slight increase in toughness observed ( Figure 5C), as more energy is required to fracture a larger number of links.…”
Section: Discussionmentioning
confidence: 99%
“…The main effect of the temperature loads is a homogenization of the behaviour between specimens, reducing the standard deviation of the measured strength values while maintaining the average values similar to the unaged control series. Foam‐filled composites produced in batches for structural applications in the building sector present a higher variability in material properties than those manufactured in bulk and under tightly controlled curing conditions for applications such as shipping and aerospace 34,35 . Therefore, the temperature could produce a post‐curing effect on the PU, leading to a higher homogeneity between specimens.…”
Section: Discussionmentioning
confidence: 99%