Abstract
This paper presented the flexural behavior of the newly developed hybrid panel which included the comparison of the ultimate load, load-deflection behavior, and failure modes. The experimental study was carried out on precast reinforced concrete-EPSfoam-steel deck hybrid panels (CES)� consist of three layers of material : concrete� layer is on the top, the steel deck is located on the bottom layer, and the EPS foam layer as the core. The dimensions of CES are 300 mm x 1200 mm with thickness of concrete layer and EPS foam as variables. The concrete thick were 30 mm and 40mm. The density of EPS foam was 12 kg/m3, 20 kg/m3, and 30 kg/m3. The static flexural test of CES was conducted in accordance with the ASTM C 393-00 standard for determination of flexural strength on concrete, the load was applied at third-point loading. This test was carried out with monotonic static load, deflection control using a loading frame with capacity of 10 kN. The results show that increase the thickness of the concrete layer from 30mm to 40mm with� EPSfoam density of 12 kg /m3, 20 kg/m3, and 30 kg/m3 achieved a maximum load increase of 33.51%; 46,13%; and 37.35%, respectively.
Highlights
The hybrid concrete structure is generally a sandwich structure consisting of two face layers separated by a core material
This include increasing the material properties of the outer layer or even differentiating the material used in the outer layer so that it can anticipate stresses caused by bending loads; namely by using a steel deck on the bottom layer so that it is strong against tensile stress, and a reinforced concrete layer on the top layer so that it is resistant to compressive stress, and an EPS foam layer as the core layer
The thickness of the concrete layer affects the maximum load of the concrete-EPSfoam-steel deck hybrid panels (CES) panel significantly
Summary
The hybrid concrete structure is generally a sandwich structure consisting of two face layers separated by a core material. The main concept proposed in this work, to improve high strength, stiffness to weight ratio, and to reduce the mass of panel. This include increasing the material properties of the outer layer or even differentiating the material used in the outer layer so that it can anticipate stresses caused by bending loads; namely by using a steel deck on the bottom layer so that it is strong against tensile stress, and a reinforced concrete layer on the top layer so that it is resistant to compressive stress, and an EPS foam layer as the core layer. The experimental study was carried out on precast reinforced concrete-EPS foam-steel deck hybrid panels (CES) consist of three layers of material: concrete layer is on the top, the steel deck is located on the bottom layer, and the EPS foam layer as the core
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