• Title/Summary/Keyword: hydration and pozzolanic reaction

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Analysis of hydration of ultra high performance concrete (초고성능 콘크리트의 수화모델에 대한 연구)

  • Wang, Hai-Long;Wang, Xiao-Yong
    • Proceedings of the Korean Institute of Building Construction Conference
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    • 2014.11a
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    • pp.13-14
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    • 2014
  • Ultra high performance concrete (UHPC) consists of cement, silica fume (SF), sand, fibers, water and superplasticizer. Typical water/binder-ratios are 0.15-0.20 with 20-30% of silica fume. The development off properties of hardening UHPC relates with both hydration of cement and pozzolanic reaction of silicafume. In this paper, by considering the production of calcium hydroxide in cement hydration and its consumption in the pozzolanic reaction, a numerical model is proposed to simulate the hydration of UHPC. The degree of hydration of cement and degree of reaction of silica fume are obtained as accompanied results from the proposed hydration model. The properties of hardening UHPC, such as degree of hydration of cement, calcium hydroxide contents, and compressive strength, are predicted from the contribution of cement hydration and pozzolanic reaction. The proposed model is verified through experimental data on concrete with different water-to-binder ratios and silica fume substitution ratios.

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Prediction of temperature distribution in hardening silica fume-blended concrete

  • Wang, Xiao-Yong
    • Computers and Concrete
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    • v.13 no.1
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    • pp.97-115
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    • 2014
  • Silica fume is a by-product of induction arc furnaces and has long been used as a mineral admixture to produce high-strength, high-performance concrete. Due to the pozzolanic reaction between calcium hydroxide and silica fume, compared with that of Portland cement, the hydration of concrete containing silica fume is much more complex. In this paper, by considering the production of calcium hydroxide in cement hydration and its consumption in the pozzolanic reaction, a numerical model is proposed to simulate the hydration of concrete containing silica fume. The heat evolution rate of silica fume concrete is determined from the contribution of cement hydration and the pozzolanic reaction. Furthermore, the temperature distribution and temperature history in hardening blended concrete are evaluated based on the degree of hydration of the cement and the mineral admixtures. The proposed model is verified through experimental data on concrete with different water-to-cement ratios and mineral admixture substitution ratios.

Assessment of the Mechanical Performance of Nano-Silica and Nano-Calcite Incorporated Limestone Calcined Clay Cement (LC3) Paste (나노실리카와 나노칼사이트 혼입 석회석 소성 점토 시멘트(LC3) 페이스트의 기계적 성능 평가)

  • Kim, Gyeong-Ryul;Cho, Seong-Min;Bae, Sung-Chul
    • Proceedings of the Korean Institute of Building Construction Conference
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    • 2023.05a
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    • pp.151-152
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    • 2023
  • This study investigates the effect of nano-silica and nano-calcite on the hydration properties and mechanical performance of limestone calcined clay cement (LC3) paste. The pastes were synthesized by replacing limestone with nano-silica and nano-calcite in order to enhance the mechanical properties in both early and late stages of hydration. The nano-calcite enhanced the strength of LC3 pastes at 1 day of hydration, however, the strength decreased compared to the ordinary LC3 pastes afterwards due to excessive amount of carboaluminate produced in the pastes. On the other hand, nano-silica improved the mechanical properties of LC3 pastes at all ages of hydration. This is mainly due to the nucleation effect and pozzolanic reaction of nano-silica, affecting the early age and late ages of hydration, respectively. The nucleation effect of both nanomaterials were confirmed by the analysis of hydration heat, supporting the enhanced early age strength of nanomaterial incorporated LC3 pastes. Furthermore, the dense matrix was shown in the pore size distribution, and the increased C-S-H due to the pozzolanic reaction evidence the improved compressive and splitting tensile strength of nano-silica incorporated LC3 pastes.

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Hydration properties of cement pastes containing high-volume mineral admixtures

  • Tang, Chao-Wei
    • Computers and Concrete
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    • v.7 no.1
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    • pp.17-38
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    • 2010
  • This research aimed to investigate the influence of high-volume mineral admixtures (MAs), i.e., fly ash and slag, on the hydration characteristics and microstructures of cement pastes. Degree of cement hydration was quantified by the loss-on-ignition technique and degree of pozzolanic reaction was determined by a selective dissolution method. The influence of MAs on the pore structure of paste was measured by mercury intrusion porosimetry. The results showed that the hydration properties of the blended pastes were a function of water to binder ratio, cement replacement level by MAs, and curing age. Pastes containing fly ash exhibited strongly reduced early strength, especially for mix with 45% fly ash. Moreover, at a similar cement replacement level, slag incorporated cement paste showed higher degrees of cement hydration and pozzolanic reaction than that of fly ash incorporated cement paste. Thus, the present study demonstrates that high substitution rates of slag for cement result in better effects on the short- and long-term hydration properties of cement pastes.

Modeling of temperature history in the hardening of ultra-high-performance concrete

  • Wang, Xiao-Yong
    • Journal of the Korea Institute of Building Construction
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    • v.14 no.3
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    • pp.273-284
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    • 2014
  • Ultra-high-performance concrete (UHPC) consists of cement, silica fume (SF), sand, fibers, water and superplasticizer. Typical water/binder ratios are 0.15 to 0.20 with 20 to 30% silica fume. In the production of ultra-high performance concrete, a significant temperature rise at an early age can be observed because of the higher cement content per unit mass of concrete. In this paper, by considering the production of calcium hydroxide in cement hydration and its consumption in the pozzolanic reaction, a numerical model is proposed to simulate the hydration of ultra-high performance concrete. The heat evolution rate of UHPC is determined from the contributions of cement hydration and the pozzolanic reaction. Furthermore, by combining a blended-cement hydration model with the finite-element method, the temperature history in the hardening of UHPC is evaluated using the degree of hydration of the cement and the silica fume. The predicted temperature-history curves were compared with experimental data, and a good correlation was found.

Effects of Replacement Ratio and Fineness of GGBFS on the Hydration and Pozzolanic Reaction of High-Strength High-Volume GGBFS Blended Cement Pastes (고강도 고로슬래그 혼합 시멘트 페이스트의 수화 및 포졸란 반응에 미치는 고로슬래그 미분말의 치환률과 분말도의 영향)

  • Jeong, Ji-Yong;Jang, Seung-Yup;Choi, Young-Cheol;Jung, Sang-Hwa;Kim, Sung-Il
    • Journal of the Korea Concrete Institute
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    • v.27 no.2
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    • pp.115-125
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    • 2015
  • This study investigated the fluidity, heat of hydration, setting time, strength development, and characteristics of hydration and pozzolanic reactions of high-strength high-volume ground granulated blast-furnace slag(GGBFS) blended cement pasts with the water-to-binder ratio of 20% by experiments, and analyzed the effects of the replacement ratio and fineness of GGBFS on the hydration and pozzolanic reaction. The results show that, in the high-strength mixtures with low water-to-binder ratio, the initial hydration is accelerated due to the "dilution effect" which means that the free water to react with cement increases by the replacement of cement by GGBFS, and thus, strengths at from 3 to 28 days were higher than those of plain mixtures with ordinary Portland cement only. Whereas it was found that the long term strength development is limited because the hydration reaction rates rapidly decreases with ages and the degree of pozzolanic reaction is lowered due to insufficient supply of calcium hydroxide according to large replacement of cement by GGBFS. Also, the GGBFS with higher fineness absorbs more free water, and thus it decreases the fluidity, the degree of hydration, and strength. These results are different with those of normal strength concrete, and therefore, should be verified for concrete mixtures. Also, to develop the high-strength concrete with high-volume of GGBFS, the future research to enhance the long-term strength development is needed.

Pozzolanic reaction of classified fly ash (분급 플라이애쉬의 포졸란반응 특성)

  • Lee, Seung-Heun;Hwang, Hae-Jeong
    • Proceedings of the Korea Concrete Institute Conference
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    • 2006.11a
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    • pp.753-756
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    • 2006
  • This paper discussed pozzolanic reaction properties of classified fly ashes by using of electrostatic precipitator. Blaine values of fly ashes at hoppers are respectively about 3000(ordinary), 5000(fine) and 8000cm2/g(super-fine). The pozzolanic reactivity of fly ash at early stage and at later stage are respectively related to the related to the fineness and the glass content of fly ash. But the early hydration of cement was retarded by addition of super fine fly ashes. the adiabatic temperature rise of mortar containing fly ash is increased with the fineness of fly ashes.

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The Effects of Na$_2$SO$_4$ on the Hydration of Fly ash Blended Cement (플라이애쉬 혼합시멘트에 미치는 Na$_2$SO$_4$의 영향)

  • 정석재;방완근;김창은
    • Journal of the Korean Ceramic Society
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    • v.35 no.11
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    • pp.1227-1232
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    • 1998
  • In order to prohibit the delay of early stage hydration activator Na2SO4 was added to Fly Ash blended ce-ment and its effects were investigated. Various measurements such as Compressive strength Heat of hy-dration Pore size distribution Hydration products Microstructure were evaluated and the results show that specimens of Fly Ash(50wt%) with 5% Na2SO4 dramatically improved the compressive strength because pozzolanic reaction of Fly Ash and the formation of ettringite make th microstructure denser than OPC and flyash cement paste.

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Fly ash-Slag-Cement Composite

  • Bang, Wan-Keun;Lee, Seung-Kyou;Lee, Seung-Heun;Kim, Chang-Eun
    • The Korean Journal of Ceramics
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    • v.6 no.3
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    • pp.286-290
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    • 2000
  • The hydration behavior of fly ash and slag on cement paste were investigated. Early stage of hydration reaction was delayed by mixing fly ash and/or slag with cement, but production of C-S-H hydrates by pozzolanic reaction densified the microstructure. The Ca/Si ratio of C-S-H hydrates in OPC and blended cement of fly ash 50%, slag 50%, fly ash+slag 50% were 2.24, 1.80, 1.82 and 1.97, respectively. The C-S-H gel with low Ca/Si ratio showed rather reticulate than needle-like structure.

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Predicting Compressive Strength of Fly Ash Mortar Considering Fly Ash Fineness (플라이 애시 미세도를 고려한 플라이 애시 모르타르의 압축 강도 예측)

  • Sun, Yang;Lee, Han-seung
    • Proceedings of the Korean Institute of Building Construction Conference
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    • 2020.11a
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    • pp.90-91
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    • 2020
  • Utilization of upgraded fine fly ash in cement-based materials has been proved by many researchers as an effective method to improve compressive strength of cement based materials at early ages. The addition of fine fly ash has introduced dilution effect, enhanced pozzolanic reaction effect, nucleation effect and physical filling effect into cement-fly ash system. In this study, an integrated reaction model is adpoted to quantify the contributions from cement hydration and pozzolanic reaction to compressive strength. A modified model related to the physical filling effect is utilized to calculate the compressive strength increment considering the gradual dissolution of fly ash particles. Via combination of these two parts, a numerical model has been proposed to predict the compressive strength development of fine fly ash mortar considering fly ash fineness. The reliability of the model is validated through good agreement with the experimental results from previous articles.

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