Ultra-High Performance Concrete: Mechanical Performance, Durability, Sustainability and Implementation Challenges

Abstract:The effects of different lightweight functional fillers on the properties of cement-based composites are investigated in this study. The fillers include fly ash cenospheres (FACs) and glass micro-spheres (GMS15 and GMS38) in various proportions. The developed composites were tested for compressive, flexural and tensile strengths at 10 and 28-day ages. The results indicated that both FACs and GMS38 are excellent candidates for producing strong lightweight composites. However, incorporation of GMS15 resulted in much lower specific strength values (only up to 13.64 kPa/kg m 3 ) due to its thinner shell thickness and lower isostatic crushing strength value (2.07 MPa). Microstructural analyses further revealed that GMS38 and GMS15 were better suited for thermal insulating applications. However, higher weight fraction of the fillers in composites leads to increased porosity which might be detrimental to their strength development.

“…2. PVA fibers were also incorporated into the mix to enhance the flexural performance of the composites (Abbas et al 2016). The PVA fibers used were 39 lm (diameter) 9 15 mm (length).…”

Section: Methodsmentioning

confidence: 99%

Effects of Different Lightweight Functional Fillers for Use in Cementitious Composites

Hanif

Cheng

et al. 2017

“…The air content in UHPC was 1% owing to using superplasticizer in the amount of 20 kg/m 3 , and a water/binder (w/b) ratio equal to 0.17 (Pierard and Cauberg 2009). A higher w/b ratio and higher superplasticizer dosage led to an increased air content (Abbas et al 2016). On the other hand, special mixing technology under lowered air pressure reduces the air content (Dils and De Schutter 2015).…”

Section: Physical and Mechanical Propertiesmentioning

confidence: 99%

Effect of Fiber Hybridization on Durability Related Properties of Ultra-High Performance Concrete

Smarzewski

Barnat-Hunek

2017

The purpose of the paper is to determine the influence of two widely used steel fibers and polypropylene fibers on the sulphate crystallization resistance, freeze-thaw resistance and surface wettability of ultra-high performance concrete (UHPC). Tests were carried out on cubes and cylinders of plain UHPC and fiber reinforced UHPC with varying contents ranging from 0.25 to 1% steel fibers and/or polypropylene fibers. Extensive data from the salt resistance test, frost resistance test, dynamic modulus of elasticity test before and after freezing-thawing, as well as the contact angle test were recorded and analyzed. Fiber hybridization relatively increased the resistance to salt crystallization and freeze-thaw resistance of UHPC in comparison with a single type of fiber in UHPC at the same fiber volume fraction. The experimental results indicate that hybrid fibers can significantly improve the adhesion properties and reduce the wettability of the UHPC surface.

“…The densification of interfacial transition zone (ITZ) (Chan and Li 1997) by (a) increasing the fineness of materials particles (Wille and Naaman 2013), (b) reducing water/binder ratio (W/B) (Beglarigale and Yazıcı 2015;Beygi et al 2013;Markovic 2006), (c) using pozzolanic materials such silica fume and quartz powder (Shaikh et al 2016;Abbas et al 2016;Chan and Chu 2004), (d) optimising surface properties through chemical treatment to increase adhesion or enhance surface roughness (Wille and Naaman 2013) and use of deformed fibres, such as corrugated fibre and hooked end fibre is a very efficient in improving bond properties and mechanical properties due to mechanical anchorage (Wu et al 2016;Wille and Naaman 2012). One of the most recommended methods to investigate the bond characteristics is through single fibre pullout test (Laranjeira de Oliveira 2010).…”

Section: Introductionmentioning

confidence: 99%

Pull-Out Behaviour of Hooked End Steel Fibres Embedded in Ultra-high Performance Mortar with Various W/B Ratios

Abdallah

Fan

Zhou

2017

This paper presents the fibre-matrix interfacial properties of hooked end steel fibres embedded in ultra-high performance mortars with various water/binder (W/B) ratios. The principle objective was to improve bond behaviour in terms of bond strength by reducing the (W/B) ratio to a minimum. Results show that a decrease in W/B ratio has a significant effect on the bondslip behaviour of both types of 3D fibres, especially when the W/B ratio was reduced from 0.25 to 0.15. Furthermore, the optimization in maximizing pullout load and total pullout work is found to be more prominent for the 3D fibres with a larger diameter than for fibres with a smaller diameter. On the contrary, increasing the embedded length of the 3D fibres did not result in an improvement on the maximum pullout load, but increase in the total pullout work.Keywords: pullout behaviour, bond mechanisms, water/binder ratio, hook geometry, embedment length and fibre-matrix interface.