Abstract
Many researchers have studied explosion prevention and fire resistance of high-strength concrete mixed with organic fiber and steel fibers. The fire resistance of high-performance fiber reinforced cement composites is desirable in terms of physical and mechanical properties. However, the use of a polymer as an alternative to organic fiber has not been clearly studied. In this study, a slurry infiltration method was used to obtain slurry-infiltrated fiber-reinforced cementitious composites (SIFRCCs) specimens. Powder polymer was used instead of organic fibers during mixing of the slurry. The compressive and flexural strengths of the specimens after 1 hr of high temperature exposure according to the KS F 2257 (ISO 834) standard fire-temperature curve were measured. The addition of the polymer before and after high temperature (about 945 °C) exposure affected the strength of the SIFRCCs. The compressive and flexural strengths were decreased after exposure to high temperature in comparison with SIFRCCs without polymer because polymer create capillary pores due to melting and burning when exposure to high temperature. This minimizes the vapor pressure inside the concrete model and reduces the failure of the concrete model. The experimental results showed that the flexural strength at a high temperature for 1.0 % polymer content was the highest at 53.8 MPa. The flexural strength was reduced by 40~50% when compared to the flexural strength before high temperature exposure and comparing to SIFRCCs without polymer, the compressive strength in 1.5% polymer is lower, owing to voids that are created in the SIFRCCs after exposure to a high temperature.
Highlights
Concrete is an economical construction material that has been used for a long time in buildings and other infrastructures in modern society
The main objective of this paper is to provide experimental data on the polymer mix slurry-infiltrated fiber-reinforced cementitious composites (SIFRCCs), compression, and bending test were performed to examine the effect of high temperature on compressive and flexural strength of specimens
Figure shows a decreased in flexural strength of SIFRCCs after exposure to high fibers were effective in reducing the degradation of flexural strength of the concrete after exposure to temperatures
Summary
Concrete is an economical construction material that has been used for a long time in buildings and other infrastructures in modern society. High-performance fiber reinforced cemented composites (HPFRCCs) can be used to provide high compressive strength and ductile behavior to address these problems. ECC has improved fire resistance due to the use of polymeric fibers, such as polyvinyl alcohol (PVA) fibers, which can melt and create channels for alleviating internal vapor pressure, preventing explosive spalling [6,7,8,9]. Slurry-infiltrated fiber-reinforced cementitious composites (SIFRCCs) and HPFRCCs in the form of SIFCON were developed to provide sufficient energy absorption capacity and excellent resistance against unexpected impacts and explosions. The polymer powder with a melting point of 120 ◦ C forms pores during melting at a high temperature, which lowers the internal water vapor pressure and minimizes structural failure, owing to explosion, impact, and fire. This study evaluated the mechanical properties of SIFRCCs before and after exposure to a high temperature using polymer powder, in replacement of organic fiber
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