Experimental and numerical investigations of thermal properties of insulated concrete sandwich panels with fiberglass shear connectors

•Paper evaluates thermal properties and energy efficiency of insulated concrete sandwich wall.•Ten large scale panels were tested using the hot box approach.•Design parameters included number, size, distribution and material of the connectors.•R-values in walls with fiberglass connectors were (2.84–...

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Bibliographic Details
Published in:Energy and buildings 2017-06, Vol.145, p.22-31
Main Authors: Woltman, Gregory, Noel, Martin, Fam, Amir
Format: Article
Language:English
Subjects:
Air temperature
Concrete construction
Concrete sandwich panel
Conductivity
Connectors
Cross-sections
Design
Design parameters
Energy consumption
Energy efficiency
Energy management
Fiber reinforced concretes
Fiber reinforced polymers
Fiberglass
Foam
Glass fiber reinforced plastics
Heat transfer
Insulation
Mathematical models
Power efficiency
Precast concrete
Prefabricated buildings
R-value
Reinforced concrete
Reinforcing steels
Sandwich panels
Sandwich structures
Steel
Studs
Temperature effects
Thermal bridging
Thermal properties
Thermal resistance
Thermodynamic properties
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Summary:•Paper evaluates thermal properties and energy efficiency of insulated concrete sandwich wall.•Ten large scale panels were tested using the hot box approach.•Design parameters included number, size, distribution and material of the connectors.•R-values in walls with fiberglass connectors were (2.84–4.68m2K/W), compared to 2.74m2K/W for steel-reinforced wall.•A one-dimensional heat transfer model was also developed to predict the R-values. A new design of a structural sandwich panel, consisting of a combination of concrete, insulation and connectors, was tested using a hot box apparatus to evaluate its thermal properties and energy efficiency. The three materials of the prefabricated panel were arranged to provide both structural and thermal efficiencies. The main objective of this work was to find the thermal resistance (R-value) of the new panel for different designs. Ten different panels were tested using the hot box approach. Each panel had a unique design in order to determine the effect of the design on the thermal behavior of the panel. The design parameters included the number, size, distribution and material of the connectors, and the number and spacing of the concrete studs. Most of the connectors were made from glass fiber reinforced polymer (GFRP) while steel connectors were used in one panel for comparison purposes. The hot box apparatus was constructed using large precast concrete box culvert units with octagonal cross sections and was carefully insulated. The metering chamber air was heated up to a temperature of 24.5°C and the climate chamber air was reduced to −4.3°C in most cases of the tested panels. The experimental R-values ranged from 2.84 to 4.68m2K/W, compared to 2.74m2K/W for the steel-reinforced control panel. A one-dimensional heat transfer model was also developed to predict the R-values.
ISSN:0378-7788
1872-6178
DOI:10.1016/j.enbuild.2017.04.007