Mechanical behavior and fatigue failure analysis of standing seam aluminum alloy roof system under temperature effect

Standing seam metal roof systems with universal high-strength, lightweight, and thin-walled characteristics have been applied worldwide in massive large-span landmark buildings, such as gymnasiums, airports, and railway stations. The existing research focuses on the wind uplift design, but there are...

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Published inJournal of Building Engineering Vol. 44; p. 103001
Main Authors Wang, Mingming, Ou, Tong, Xin, Zhiyong, Wang, Dayang, Zhang, Yongshan
Format Journal Article
LanguageEnglish
Published Elsevier Ltd 01.12.2021
Subjects
Experiments
Mechanical behavior
Standing seam metal roof system
Temperature effect
Wear analysis
Temperature effect
Mechanical behavior
Standing seam metal roof system
Wear analysis
Experiments
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Abstract Standing seam metal roof systems with universal high-strength, lightweight, and thin-walled characteristics have been applied worldwide in massive large-span landmark buildings, such as gymnasiums, airports, and railway stations. The existing research focuses on the wind uplift design, but there are few studies on the mechanical properties under the temperature effect. In this paper, the temperature effect of the standing seam aluminum alloy roof (SSAAR) system was studied. To be familiar with the mechanical and deformation characteristics of the SSAAR system, the static loading tests under different temperatures and boundary constraints were carried out. Two specimens, one with anti-wind clips and the other without anti-wind clips, were further tested under cyclic loading to evaluate and quantify the fatigue failure characteristics of the roof system. The testing results indicate that the stress concentration, thermal expansion displacement, and wear of the SSAAR system are significant. The slab rib stress is the largest, accounting for about 83.7% of the yield strength, followed by the slab surface stress, and the slab bottom stress is the smallest. The horizontal displacement is greater than the vertical displacement, and the maximum is about 20.42 mm. The boundary constraint mainly affects the support stress and vertical displacement to increase by 47.2% and 79.3% respectively. The anti-wind clips mainly increase the wear thickness of the roof slab, which is increased by 67.5%. •The stress concentration and thermal expansion displacement of the SSAAR system are significant.•The slab rib stress is the largest, followed by the slab surface stress, and the slab bottom stress is the smallest.•The horizontal displacement is greater than the vertical displacement.•The wear thickness of the roof slab is larger than that of support.
AbstractList Standing seam metal roof systems with universal high-strength, lightweight, and thin-walled characteristics have been applied worldwide in massive large-span landmark buildings, such as gymnasiums, airports, and railway stations. The existing research focuses on the wind uplift design, but there are few studies on the mechanical properties under the temperature effect. In this paper, the temperature effect of the standing seam aluminum alloy roof (SSAAR) system was studied. To be familiar with the mechanical and deformation characteristics of the SSAAR system, the static loading tests under different temperatures and boundary constraints were carried out. Two specimens, one with anti-wind clips and the other without anti-wind clips, were further tested under cyclic loading to evaluate and quantify the fatigue failure characteristics of the roof system. The testing results indicate that the stress concentration, thermal expansion displacement, and wear of the SSAAR system are significant. The slab rib stress is the largest, accounting for about 83.7% of the yield strength, followed by the slab surface stress, and the slab bottom stress is the smallest. The horizontal displacement is greater than the vertical displacement, and the maximum is about 20.42 mm. The boundary constraint mainly affects the support stress and vertical displacement to increase by 47.2% and 79.3% respectively. The anti-wind clips mainly increase the wear thickness of the roof slab, which is increased by 67.5%. •The stress concentration and thermal expansion displacement of the SSAAR system are significant.•The slab rib stress is the largest, followed by the slab surface stress, and the slab bottom stress is the smallest.•The horizontal displacement is greater than the vertical displacement.•The wear thickness of the roof slab is larger than that of support.
ArticleNumber 103001
Author Zhang, Yongshan
Ou, Tong
Wang, Mingming
Xin, Zhiyong
Wang, Dayang
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crossref_primary_10_1007_s12205_021_0633_5
crossref_primary_10_1016_j_applthermaleng_2023_120169
crossref_primary_10_3390_met13081452
crossref_primary_10_1088_2631_8695_ac8786
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Keywords Temperature effect
Mechanical behavior
Standing seam metal roof system
Wear analysis
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Snippet Standing seam metal roof systems with universal high-strength, lightweight, and thin-walled characteristics have been applied worldwide in massive large-span...
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SubjectTerms Experiments
Mechanical behavior
Standing seam metal roof system
Temperature effect
Wear analysis
Title Mechanical behavior and fatigue failure analysis of standing seam aluminum alloy roof system under temperature effect
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