Influence of aggregate characteristics on concrete performance

Bentz, Dale P.; Arnold, J.; Boisclair, M.; Jones, Scott Z.; Rothfeld, Paul; Stutzman, Paul E.; Tanesi, Jussara; Mengesha, Beyene; Kim, Hae Jin; Muñoz, José F.; Ardani, Ahmad

doi:10.6028/nist.tn.1963

Cited by 18 publications

(6 citation statements)

References 32 publications

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“…At the FHWA laboratory, an ordinary portland cement, ASTM C150-16 Type I/II, with a manufacturer-reported Blaine fineness of 382 m 2 /kg and density of 3070 kg/m 3 , was used to prepare a concrete with exposed aggregates to serve as the existing substrate [14], with the fine aggregate (FA) being an ordinary river sand (apparent specific gravity of 2.59) and the coarse aggregate (CA) being a dolomitic limestone (apparent specific gravity of 2.85). Dolomitic limestone aggregates have been observed to provide good bonding to paste and high strengths (compressive, flexural, and splitting tensile) and elastic modulus in both ordinary portland cement and ternary blend (cement, fly ash, and fine limestone) concretes in a recent joint NIST/FHWA study of the influence of aggregate characteristics on concrete performance [28]. For the present study, the concrete mixture was developed with a water-to-cement ratio ( w/c ) of 0.35 by mass, cement:FA:CA ratio of 1:1.7:2.5 (by mass), a minimum slump of 76 mm (3 in.)…”

Section: Methodsmentioning

confidence: 99%

Influence of substrate moisture state and roughness on interface microstructure and bond strength: Slant shear vs. pull-off testing

Bentz

Varga

Muñoz

et al. 2018

Cement and Concrete Composites

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There are conflicting views in the literature concerning the optimum moisture state for an existing substrate prior to the application of a repair material. Both saturated-surface-dry (SSD) and dry substrates have been found to be preferable in a variety of studies. One confounding factor is that some studies evaluate bonding of the repair material to the substrate via pull-off (direct tension) testing, while others have employed some form of shear specimens as their preferred testing configuration. Available evidence suggests that dry substrate specimens usually perform equivalently or better in shear testing, while SSD ones generally exhibit higher bond strengths when a pull-off test is performed, although exceptions to these trends have been observed. This paper applies a variety of microstructural characterization tools to investigate the interfacial microstructure that develops when a fresh repair material is applied to either a dry or SSD substrate. Simultaneous neutron and X-ray radiography are employed to observe the dynamic microstructural rearrangements that occur at this interface during the first 4 h of curing. Based on the differences in water movement and densification (particle compaction) that occur for the dry and SSD specimens, respectively, a hypothesis is formulated as to why different bond tests may favor one moisture state over the other, also dependent on their surface roughness. It is suggested that the compaction of particles at a dry substrate surface may increase the frictional resistance when tested under slant shear loading, but contribute relatively little to the bonding when the interface is submitted to pull-off forces. For maximizing bond performance, the fluidity of the repair material and the roughness and moisture state of the substrate must all be given adequate consideration.

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Section: Methodsmentioning

confidence: 99%

Influence of substrate moisture state and roughness on interface microstructure and bond strength: Slant shear vs. pull-off testing

Bentz

Varga

Muñoz

et al. 2018

Cement and Concrete Composites

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“…In the past decade, the United States' production has grown from 67 million metric tons to 90 million (Lehne and Preston 2018). OPC composites in the form of mortar and concrete create structures such as sidewalks, foundations, floors, and columns, and the desired strengths for each application has been varied and optimized over time (Bentz et al 2017;Vu et al 2020). GP composites have been regarded highly in the literature due to high mechanical properties, namely compressive and flexural strength, and the relatively low-emission production of metakaolin is desirable in using GP composites as an alternative to concrete (Ramujee and PothaRaju 2017).…”

Section: Mechanical Properties Of Ordinary Portland Cement (Opc) Comp...mentioning

confidence: 99%

“…A low cement and aggregate ratio, such as a mixture with too much sand, also lowers the mechanical strength of concrete and results in a grainy texture that will be unable to bind together. The shape, size, and strength of the aggregates used are important, especially when making concrete with sand and coarse aggregates such as gravel (Bentz et al 2017;Vu et al 2020;Abdullahi 2012;The Engineering ToolBox 2009).…”

Section: Mechanical Properties Of Ordinary Portland Cement (Opc) Comp...mentioning

confidence: 99%

4D printing structures for extreme temperatures using metakaolin based geopolymers

Al-Chaar¹,

Brandvold²,

Kozych³

et al. 2023

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Geopolymers (GPs) are a class of amorphous, aluminosilicate-based ceramics that cure at room temperature. GPs are formed by mixing an aluminosilicate source, which is metakaolin in this case, with an alkali activator solution, which can be either sodium or potassium water glass. GPs have attracted interest for use in structural applications over the past few decades because they have superior mechanical properties to ordinary Portland cement (OPC). Additionally, they can tolerate much higher temperatures and produce a fraction of the CO₂ compared to OPC. This project aims to develop geopolymer composites for 4D printing (the fourth dimension being time) and test their mechanical properties. Rheology and the effects of curing in ambient conditions will be evaluated for fresh geopolymer. Freeze-thaw resistance will be evaluated on potentially printable composites for extreme temperature resistance, etc.

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“…Table 2 reports the properties of each phase. Bulk and shear moduli are taken from [3]. The permeability of aggregates is very low compared to mortars permeability.…”

Section: Estimates Of Elastic Propertiesmentioning

confidence: 99%

“…Altogether, these aspects lead to changes in the properties of a superficial layer, and these changes can be relevant to some applications of cement-based materials and concrete structures potentially affecting their performances [1], [2]. The skin of the concrete is in direct contact with aggressive agents such as chlorides and carbon dioxide [3]. If it has weaker properties than the bulk area of the material, this implies an increase in the risk of the appearance of pathologies or the acceleration of its appearance.…”

Section: Introductionmentioning

confidence: 99%

Numerical and Experimental Investigation of Wall Effect in Concrete

et al. 2022

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This study presents a new numerical approach using tools developed to perform a molecular simulation to investigate the wall effect on aggregates and mortar distribution in concrete. Aggregates are represented by spheres interacting via a generalized truncated Lennard-Jones potential. This approach allows obtaining the particle profiles according to the reference frame of interest (e.g., the confined directions). Then the particle-based distributions are transformed into continuum profiles of volume fractions using a convolution. Based on volume fraction profiles, transport or mechanical properties are estimated by the Mori-Tanaka scheme from classical homogenization. Results are compared to experimental work. The numerical method could be generalized and used for other applications in different fields. In civil engineering, perspectives include using the aggregate distribution to conduct a finer analysis, and the results would be extremely relevant for the prediction of the water content profile and the evolution of pathologies such as carbonation, corrosion, ISR, etc.

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Influence of aggregate characteristics on concrete performance

Cited by 18 publications

References 32 publications

Influence of substrate moisture state and roughness on interface microstructure and bond strength: Slant shear vs. pull-off testing

Influence of substrate moisture state and roughness on interface microstructure and bond strength: Slant shear vs. pull-off testing

4D printing structures for extreme temperatures using metakaolin based geopolymers

Numerical and Experimental Investigation of Wall Effect in Concrete

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