Flexural behavior of PVC stay-in-place formed RC walls

•PVC stay-in-place forming system enhanced the flexural behavior of RC walls.•Effect of the PVC on the yield load decreased as the reinforcement ratio increased.•PVC increase to ultimate loads depends on concrete thickness and/or reinforcement ratio.•PVC enhanced the ductility of the wall system wit...

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Bibliographic Details
Published in:Construction & building materials 2013-11, Vol.48, p.830-839
Main Authors: Wahab, Noran, Soudki, Khaled A.
Format: Article
Language:English
Subjects:
Analysis
Bending
Compression
Concrete
Concrete walls
Connectors
Cracks
Flat panel displays
Flexure
Polyvinyl chloride
Properties
PVC
Reinforced concrete
Rupture
Static load
Stay-in-place formwork
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Summary:•PVC stay-in-place forming system enhanced the flexural behavior of RC walls.•Effect of the PVC on the yield load decreased as the reinforcement ratio increased.•PVC increase to ultimate loads depends on concrete thickness and/or reinforcement ratio.•PVC enhanced the ductility of the wall system with an increase in ultimate deflection.•A model was proposed to predict the capacity of the PVC encased walls. The study experimentally investigates the flexural behavior of concrete wall strips encased with PVC stay-in-place (SIP) concrete forming system. The system consists of interconnected Polyvinyl chloride (PVC) elements; panels, connectors and bracings. Thirty PVC encased wall specimens were cast with dimensions: 457mm wide by 200mm or 250mm deep by 3050mm long. The variables studied were: the concrete core thickness (200mm or 250mm), the reinforcement ratio, and the connector type (middle and braced connector). The connectors used were middle connectors with flat panels or connectors with inclined bracing on the compression side and insulation (foam) on the tension side. All the specimens were tested under four point bending with a shear span of 1150mm. The test results showed that the PVC stay-in-place formwork system was effective in enhancing the flexural behavior of the encased walls. For a given reinforcement, the PVC encased specimens cracked and failed in the same mode, regardless of the connector type or the concrete core’s thickness. The PVC encased walls exhibited higher yield and ultimate loads in comparison to control walls. The increase in load for the PVC encased walls decreased with higher reinforcement ratios. The contribution of the PVC stay-in-place system to the ultimate load increased as the concrete core thickness decreased and/or as the reinforcement ratio decreased. A model based on strain compatibility was developed to predict the flexural capacity of PVC stay-in-place encased walls. Predictions were in close agreement with measured results.
ISSN:0950-0618
DOI:10.1016/j.conbuildmat.2013.07.073