Investigation of effects of Portland cement fineness and alkali content on concrete plastic shrinkage cracking

Yang, Kai; Zhong, Mingquan; Magee, Bryan; Yang, Chen; Chong, Wang; Zhu, Xiaohong; Zhang, Zhilu

doi:10.1016/j.conbuildmat.2017.03.130

Cited by 41 publications

(26 citation statements)

References 27 publications

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“…Furthermore, it has been observed that a normal hardening cement boosts the cracking tendency of SCC in comparison to a rapid hardening cement [4]. Finer cement particles, on the other hand, increase the cracking severity [12,13], most probably due to autogenous shrinkage. However, coarser cements cause wider cracks, despite of lower cracking intensity [13].…”

Section: Introductionmentioning

confidence: 99%

“…Finer cement particles, on the other hand, increase the cracking severity [12,13], most probably due to autogenous shrinkage. However, coarser cements cause wider cracks, despite of lower cracking intensity [13]. Another study shows that superplasticizers (SP) increase the evaporation, delay the hydration, and lead to higher cracking risk [14].…”

Section: Introductionmentioning

confidence: 99%

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Plastic Shrinkage Cracking of Self-compacting Concrete: Influence of Capillary Pressure and Dormant Period

Sayahi

Emborg²,

Hedlund

et al. 2019

Nordic Concrete Research

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This research investigates the effect of capillary pressure and the length of the hydration dormant period on the plastic shrinkage cracking tendency of SCC by studying specimens produced with different w/c ratios, cement types and SP dosages. A relationship between the capillary pressure rate and the length of the hydration dormant period is defined, which can explain the cracking severity of the concrete when the volumetric deformation is unknown. The results show, that the cracking tendency of SCC was the lowest in case of w/c ratio between 0.45 and 0.55, finer and more rapid hardening cement, and lower dosage of SP. The dormant period was prolonged by increasing the w/c ratio, using coarser cement, and higher SP dosage. It was concluded that the cracking tendency of concrete is a function of the capillary pressure buildup rate and the length of the dormant period.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Plastic Shrinkage Cracking of Self-compacting Concrete: Influence of Capillary Pressure and Dormant Period

Sayahi

Emborg²,

Hedlund

et al. 2019

Nordic Concrete Research

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“…Thus Building concretes showed lower shrinkage rate than civil engineering concretes in spite of higher drying flux for building concretes. Kai et al [30] found that an increase in cement surface area resulted in lower evaporation rate but higher plastic shrinkage. Slowik et al [29] also showed that early age cracking risk increases with decreasing particle sizes.…”

Section: -Cenmentioning

confidence: 99%

“…Plastic shrinkage depends on water-to-binder (W/B) ratio and cement fineness [29]. An increase in cement fineness and a decrease in W/B ratio led to a decrease in the bleeding rate and an increase the capillary tension level [30]. Plastic shrinkage strain is reduced when the evaporated water is replaced by bleeding water, which could be provided by saturated recycled concrete aggregates [31].…”

Section: Introductionmentioning

confidence: 99%

Early age behaviour of recycled concrete aggregates under normal and severe drying conditions

Souche

Bendimerad

Rozière

et al. 2017

Journal of Building Engineering

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The use of recycled aggregates in concrete mixtures is a part of waste recovery strategy. The French national project RECYBETON aims at developing scientific knowledge to facilitate the use of recycled aggregates into concrete. In this experimental study, two exposure conditions were combined to analyse the behaviour of fresh and hardening concrete in standard and severe drying conditions (8 m.s -1 wind speed). High evaporation rate promotes the development of plastic shrinkage and cracking of fresh concrete. The influence of recycled concrete aggregates proportion and initial water saturation rate were investigated. Two series of concrete mixtures were designed to reach two strength classes. The strains and weight loss of concrete samples were monitored until the stabilization of plastic shrinkage. The increase in evaporation rate accelerated the development and increased the maximum value of plastic shrinkage but did not significantly influence the shrinkageto-weight loss ratios. In severe conditions plastic shrinkage developed before initial setting thus reached higher magnitudes. The main mix-design parameter affecting the shrinkage-to-weight loss ratio and cracking was the total water-to-binder ratio. The total water content includes the water added and the water used to pre-saturate the aggregates. High evaporation rate triggered the release of water initially absorbed by recycled concrete aggregates.

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“…After 300 times of freezing-thawing cycles, the mass loss of RPC with 40% SP is 0.32% and the relative dynamic modulus is 99.3%. Based on the reports about the shrinkage [6][7], freezing-thawing cycles [8][9], and permeability of chloride ions [10][11] for ordinary concrete and RPC, when the SF is replaced by 40% SP, the compactness of the mortar or concrete will be improved with "Filling effect" of SP, which is due to a small particle size that is smaller than cement particle size and bigger than SF particle size. Generally speaking, more compact or less water means less porosity and penetration channel for ions or solution, which finally leads to a better volume stability, a lower mass loss and a higher relative dynamic modulus under freezing-thawing cycles, and a lower electric flux under the penetration of chlorid ions (Table 4).…”

Section: Introductionmentioning

confidence: 99%

The durability of RPC with different content of silicon powder

Han¹,

Sun²,

Li³

et al. 2017

AIP Conference Proceedings

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Abstract. The volume stability, freezing-thawing cycles, the resistance of chloride ions and sulfate attack of RPC with different content (0%, 40%, 100%) of silicon powder are investigated in this paper. The results demonstrate that the volume stability and the resistance of freezing-thawing for RPC with 40% silicon powder are improved because of a high compactness, whose shrinkage is only 350 × 10 -6 for 60 d and tends to this value after 60 d, and the relative dynamic modulus is more than 99% after 300 times of freezing-thawing cycles. Meanwhile, with a high content of active SiO2 and a low magnesium content, the resistance of chloride ions and sulfate attack of RPC with 40% silicon powder are improved attributing to a high compact structure and a low level of magnesium sulfate attack. This leads an increase of the compressive strength with 5.6% after 150 times of wetting-drying cycles in the solution with 5% Na2SO4.

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Investigation of effects of Portland cement fineness and alkali content on concrete plastic shrinkage cracking

Cited by 41 publications

References 27 publications

Plastic Shrinkage Cracking of Self-compacting Concrete: Influence of Capillary Pressure and Dormant Period

Plastic Shrinkage Cracking of Self-compacting Concrete: Influence of Capillary Pressure and Dormant Period

Early age behaviour of recycled concrete aggregates under normal and severe drying conditions

The durability of RPC with different content of silicon powder

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