Feasibility of producing ultra-high performance concrete with high elastic modulus by steel chips: An experimental study

Chu, Huaqiang; Gao, Li; Qin, Jianjian; Jiang, Jinyang; Wang, Fengjuan

doi:10.1016/j.conbuildmat.2023.130964

Cited by 7 publications

(1 citation statement)

References 35 publications

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“…These ndings suggest that the optimization was successful in making M2 stiffer than M1, which is a desirable outcome. It is worth noting that a higher AVCM is considered advantageous for enhancing the material's durability and resistance to pathological manifestations (Chu et al, 2022(Chu et al, , 2023Liang et al, 2022b).…”

Section: Splitting Tensile Strength Results Mortars Formulationsmentioning

confidence: 99%

Complex Modulus characterization of an Optimized Binder with SCMs: proposition of an enhanced Cement formulation to improve Stiffness Behavior and Durability of Mortars and Concretes

et al. 2023

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Materials optimization is an aspect of continuous endeavor for civil engineering in many applications, especially in construction where the materials' durability and mechanical performance are crucial for structural integrity. Structures such as aerogenerators, both towers and foundations, are highly susceptible to cyclic loads with a broad range of frequencies and levels. The improvement of the stiffness behavior can signi cantly enhance their fatigue resistance and consequently durability. This paper aims to evaluate the impact of a high-performance binder optimization, using supplementary cementitious materials (SCMs) to improve the mechanical behavior of mortars and concretes, by improving stiffness response under dynamic loading, which is related to durability and fatigue lifeservice. Static tests (axial compressive and splitting tensile strengths) were conducted as well as cyclic stiffness tests that were proposed as a new methodology for these kinds of materials, that may better relate to dynamic behavior in eld. The proposition consists of testing complex modulus tests under sinusoidal loading either in pure compression or in pure tension, adopting low (0.1 Hz to 1 Hz) and midrange (1 Hz to 25 Hz) loading frequencies. The results show that the optimized binder resulted in a superior material with up to 23% stiffer loading response and 13.8% more energy storage elastically, with also inferences on improved durability, which is expected to delay pathological manifestations. The proposed testing protocol obtained results compatible with the literature and seems applicable for evaluating the dynamic behavior of cementitious materials.

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Section: Splitting Tensile Strength Results Mortars Formulationsmentioning

confidence: 99%