Sukhoon Pyo scite author profile

Although ultra high-performance concrete (UHPC) has great performance in strength and durability, it has a disadvantage in the environmental aspect; it contains a large amount of cement that is responsible for a high amount of CO2 emissions from UHPC. Supplementary cementitious materials (SCMs), industrial by-products or naturally occurring materials can help relieve the environmental burden by reducing the amount of cement in UHPC. This paper reviews the effect of SCMs on the properties of UHPC in the aspects of material properties and environmental impacts. It was found that various kinds of SCMs have been used in UHPC in the literature and they can be classified as slag, fly ash, limestone powder, metakaolin, and others. The effects of each SCM are discussed mainly on the early age compressive strength, the late age compressive strength, the workability, and the shrinkage of UHPC. It can be concluded that various forms of SCMs were successfully applied to UHPC possessing the material requirement of UHPC such as compressive strength. Finally, the analysis on the environmental impact of the UHPC mix designs with the SCMs is provided using embodied CO2 generated during the material production.

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Direct tensile behavior of ultra high performance fiber reinforced concrete (UHP-FRC) at high strain rates

Pyo

El‐Tawil

Naaman

2016

Cement and Concrete Research

129

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This experimental study investigates the direct tensile behavior of ultra-high performance fiber reinforced concrete (UHP-FRC) at strain rates ranging from 90 to 146 /sec. The tests are conducted using a recently developed impact testing system that uses suddenly released strain energy to generate an impact pulse. Three fiber types were considered, a twisted fiber and two other types of straight fibers. Specimen impact response was evaluated in terms of first cracking strength, post cracking strength, energy absorption capacity and strain capacity. The test results indicate that specimens with twisted fibers generally exhibit somewhat better mechanical properties than specimens with straight fibers for the range of strain rates considered. All UHP-FRC series tested showed exceptional rate sensitivities in energy absorption capacity, generally becoming much more energy dissipative under increasing strain rates. This characteristic highlights the potential of UHP-FRC as a promising cement based material for impact-and blastresistant applications.

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On joint strengths, peel stresses and failure modes in adhesively bonded double-strap and supported single-lap GFRP joints

Lee

Pyo

Kim

2009

Composite Structures

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Sukhoon Pyo

Strain rate dependent properties of ultra high performance fiber reinforced concrete (UHP-FRC) under tension

Fresh and hardened properties of ultra-high performance concrete incorporating coal bottom ash and slag powder

The Role of Supplementary Cementitious Materials (SCMs) in Ultra High Performance Concrete (UHPC): A Review

Direct tensile behavior of ultra high performance fiber reinforced concrete (UHP-FRC) at high strain rates

On joint strengths, peel stresses and failure modes in adhesively bonded double-strap and supported single-lap GFRP joints

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