Abstract
Recently, many residents living in apartment buildings in Korea have been bothered by noise coming from the houses above. In order to reduce noise pollution, communities are increasingly imposing bylaws, including the limitation of floor impact sound, minimum thickness of floors, and floor soundproofing solutions. This research effort focused specifically on the deflection of resilient materials in the floor sound insulation systems of apartment houses. The experimental program involved conducting twenty-seven material tests and ten sound insulation floating concrete floor specimens. Two main parameters were considered in the experimental investigation: the seven types of resilient materials and the location of the loading point. The structural behavior of sound insulation floor floating was predicted using the Winkler method. The experimental and analytical results indicated that the cracking strength of the floating concrete floor significantly increased with increasing the tangent modulus of resilient material. The deflection of the floating concrete floor loaded at the side of the specimen was much greater than that of the floating concrete floor loaded at the center of the specimen. The Winkler model considering the effect of modulus of resilient materials was able to accurately predict the cracking strength of the floating concrete floor.
Highlights
Residential high-rise buildings have been gaining increasing popularity in densely populated countries due to their favorable properties
The structural behavior of ten floating concrete floor specimens was observed from the experimental tests
The rate of load reduction of the PE specimens with respect to increasing deflection was greater than that of the Ethylene polystyrene (EPS) specimen but was similar to that of the tire chip (TC) and glass wool (GW) specimens
Summary
Residential high-rise buildings have been gaining increasing popularity in densely populated countries due to their favorable properties. Test results indicated that floating concrete floors must be carefully installed to reduce the annoyance caused by impact sound transmission between rooms in residential buildings. Test results [12, 13] in the literature indicated that the density and the slab contact area of materials increased the dynamic stiffness of the material. The placing of resilient materials between the reinforced concrete slab and finishing mortar should reduce the floor impact sound vibration from the floor and support the load on the floor. Soft resilient materials in floor sound insulation systems may not support the load on the floor and cause to crack on the finishing mortar and sink the floor. It is proposed that the current study, findings on the cracking strength of floating floor systems, may provide useful information on the applicability of resilient materials on the floating floor systems
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