Material Properties of Ultra - High Performance Concrete in Extreme Conditions

David Citek; Milan Rydval; Stanislav Rehacek; Jiří Kolisko

doi:10.4028/www.scientific.net/KEM.711.157

Paper Titles

Design of Massive Casting Controlling Early Age Properties of Concrete
p.126

Water Transport Properties and Depth of Chloride Penetration in Ultra High Performance Concrete
p.137

Autogenous Shrinkage in High Performance Concrete with Chemical Admixtures
p.143

High Stiffness Concrete for Tall Buildings under Severe Conditions: Mix Design and Structural Member Test
p.150

Material Properties of Ultra - High Performance Concrete in Extreme Conditions
p.157

Impact Properties of Hemp Fibre Reinforced Cementitious Composites
p.163

Ultra High Performance Fiber Reinforced Concrete Behavior under Static and High Velocity Impact
p.171

The Influence of Steel Fibers on the Dynamic Response of Self-Compacting Concrete
p.179

Effect of Fiber Type and Fiber Hybrids on Strain-Hardening and Multiple Cracking Properties of the Ultra-High Performance Cementitious Composites under Uniaxial Loads
p.187

HomeKey Engineering MaterialsKey Engineering Materials Vol. 711Material Properties of Ultra - High Performance...

Material Properties of Ultra - High Performance Concrete in Extreme Conditions

Abstract:

The Ultra High Performance Concrete (UHPC) is a very promising material suitable for application in special structures. However, the knowledge of performance of this relatively new material is rather limited. The exceptional mechanical properties of UHPC allow for a modification of the design rules, which are applicable in ordinary or high strength concrete. This paper deals in more detail with impact of thermal stress on bond properties between prestressing strands and UHPC and an influence of high temperature to final material properties of different UHPC mixtures. Specimens in the first experimental part were subjected to the cycling freeze-thaw testing. The relationship between bond behavior of both type of material (UHPC and ordinary concrete) and effect of cycling freeze-thaw tests was investigated. The second part of experimental work was focused on mechanical properties of UHPC exposure to the high temperature (T_max = 200°C to T_max = 1000°C). Tested mechanical properties were compressive and flexural strengths, the fracture properties will be presented in the next paper. The obtained experimental data serve as a basis for further systematic experimental verification and more accurate information about the significantly higher material properties of UHP(FR)C and its behavior in extreme conditions.

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Periodical:

Key Engineering Materials (Volume 711)

Pages:

157-162

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.711.157

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Online since:

September 2016

Authors:

David Citek*, Milan Rydval, Stanislav Rehacek, Jiří Kolisko

Keywords:

Bond, Extreme Condition, High Temperature, Strength, Ultra-High Performance Concrete (UHPC)

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References

[1] Čítek, D., Huňka, P., Řeháček, S., Mandlík, T., Kolísko, J.: Testing of Bond Behaviour of UHPC In.: Advanced Materials Research, Vol 1054, pp.95-98, Trans Tech Publications, Switzerland, (2014).

DOI: 10.4028/www.scientific.net/amr.1054.95

Google Scholar

[2] Vítek, J.L., Coufal, R., Čítek, D.: UHPC - Development and testing on structural elements. In Concrete and Concrete Structures 2013, Žilina, 2013, University of Žilina, str. 218-223, ISSN 18777058.

DOI: 10.1016/j.proeng.2013.09.033

Google Scholar

[3] ČSN 73 1333 Testing of bond between prestressing strands and concrete, Vydavatelství norem, Prague, (1989).

Google Scholar

[4] Phan L.T., High-Strength concrete at high temperature – an overview. Online at http: /fire. nist. gov/bfrlpubs/build02/PDF/b02171. pdf.

Google Scholar

[5] Abrams M.S., Compressive strength of concrete at temperatures to 1600 °F, ACI SP 25, Temperature and concrete, Detroit, Michigan, (1971).

Google Scholar

[6] Recommendation of RILEM TC 200-HTC: mechanical concrete properties at high temperatures—modelling and applications, Part 1: Introduction—General presentation, In Materials and Structures (2007) 40: 841–853, doi 10. 1617/s11527-007-9285-2.

DOI: 10.1617/s11527-007-9285-2

Google Scholar

[7] Schneider U, Schwesinger P (eds) (1990) Mechanical testing of concrete at high temperatures. RILEM Transaction 1, February 1990, ISBN: 3-88122-565-X, 72.

Google Scholar

[8] Schneider U, Properties of materials at high temperatures – Concretes. RILEM-Report 44-PHT, 2nd Edn, Kassel, June (1986).

Google Scholar

[9] AFGC, and SETRA: Ultra-High Performance Fibre Reinforced Concrete-Interim Recommendations, France, (2013).

Google Scholar