The Effect of Incorporating Ultra-Fine Spherical Particles on Rheology and Engineering Properties of Commercial Ultra-High-Performance Grout

Lin, Wei‐Ting; Zhao, Wen-Que; Chang, Yi-Hua; Yang, Jiann-Shi; Cheng, An

doi:10.3390/cryst11091040

Cited by 3 publications

(1 citation statement)

References 63 publications

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“…SF could not be used until the late 1960s or early 1970s after the Norwegian government announced environmental legislation involving huge improvements in filtering technology [60]. SF nanoparticles (0.1 to 0.3 µm) are 100 times smaller than cement particles [65]. SF particles are spherical, while the color varies from greyish-black powder to premium white.…”

Section: Silica Fumementioning

confidence: 99%

A Review on Emerging Cementitious Materials, Reactivity Evaluation and Treatment Methods

2023

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Alternative to traditional concrete, sustainable concrete reduces cement content, waste management issues, and CO2 emissions. To achieve sustainable concrete, waste materials can be used as supplementary cementitious materials (SCMs) to partially replace cement. Fly ash, ground-granulated blast furnace slag, and silica fume have been heavily studied as SCMs. However, due to the retirement of coal-fired power plants and switching to renewable energy, existing SCMs are losing their dominance. With SCMs becoming more widely accepted as partial cement substitutes, there is fear that the current supply will not meet future demand. As a result, researchers have been looking for alternative SCMs. The circular economy can be achieved by reusing non-hazardous construction and demolition materials, timber, and metal/steel production waste as SCMs. This article discusses emerging SCMs, reactivity evaluation methods, their limitations, and treatment methods that may improve reactivity. Emerging SCMs can replace existing SCMs in quantity, but their supply to cement factories and low reactivity due to stable crystallinity hinders their use. Among treatment methods, particle size reduction effectively enhances reactivity; however, very fine SCM may increase the overall water demand due to the large surface area. Decades-old reactivity evaluation methods have relatively weak correlations and thus misreport the reactivity of SCMs. Newer R3 models, such as calorimetry and bound water, give the best correlations (R ≥ 0.85) for 28-day relative strength and better performance. Additionally, more concrete testing with emerging SCMs under different durability and environmental protection conditions is required and life cycle assessments are needed to determine their regional environmental impact.

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Section: Silica Fumementioning

confidence: 99%

A Review on Emerging Cementitious Materials, Reactivity Evaluation and Treatment Methods

2023

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Enhancing the radiographic imaging of void defects in grouts by attenuation coefficient modification of grouting materials

Otoo

et al. 2023

Radiation Physics and Chemistry

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Rheological Properties of Cement Paste Containing Ground Fly Ash Based on Particle Morphology Analysis

Zhang

Wang

et al. 2022

Crystals

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Separating finer particles from raw fly ash is a popular method to produce high-performance admixture of concrete. However, the supply of separated fly ash is obviously behind the demand and the residue fly ash is difficult to be disposed. Ground fly ash is another method to improve the particle size and reactivity, but the change of particle morphology during grinding may affect the rheological properties of cement paste and concrete, which limits the application of ground fly ash in concrete projects. In this study, the raw fly ash, separated fly ash, and ground fly ash of the same particle size range were studied and the particle morphology was analyzed by Image-Pro Plus process and spherical particles proportion calculation. On this basis, the fluidity and rheological properties of cement paste with different fly ash content were tested and the mechanism was discussed by packing density and zeta potential analysis. The results showed that the total amount of spherical particles in fly ash-cement paste system was reduced due to the spherical particles of ground fly ash being destroyed during the grinding process. Thus, compared with the separated fly ash of similar particle size range, the fluidity of ground fly ash was significantly decreased while the yield stress and plastic viscosity increased significantly, which indicated that the rheological properties of fly ash cement paste are closely related to the particle morphology of fly ash. The results provide theoretical basis and technology support to the application of ground fly ash.

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The Effect of Incorporating Ultra-Fine Spherical Particles on Rheology and Engineering Properties of Commercial Ultra-High-Performance Grout

Cited by 3 publications

References 63 publications

A Review on Emerging Cementitious Materials, Reactivity Evaluation and Treatment Methods

A Review on Emerging Cementitious Materials, Reactivity Evaluation and Treatment Methods

Enhancing the radiographic imaging of void defects in grouts by attenuation coefficient modification of grouting materials

Rheological Properties of Cement Paste Containing Ground Fly Ash Based on Particle Morphology Analysis

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