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Home > Publications > International Concrete Abstracts Portal
The International Concrete Abstracts Portal is an ACI led collaboration with leading technical organizations from within the international concrete industry and offers the most comprehensive collection of published concrete abstracts.
Showing 1-5 of 38 Abstracts search results
Document:
SP302-13
Date:
June 1, 2015
Author(s):
Ahmad Habbaba and Johann Plank
Publication:
Symposium Papers
Volume:
302
Abstract:
In portland slag cements (PSC), different slag compositions can produce variations in workability due to the disparity in the surface chemistry of the slags. Here, the surface chemistry of different PSCs dispersed in water was studied in the absence and presence of polycarboxylate (PCE) superplasticizers. Six PSCs were prepared by mixing portland cement with 30 or 70 wt.% of three slags. As PCEs, two copolymers based on methacrylic acid–co–?–methoxy poly(ethylene glycol) methacrylate ester were employed. It was found that the slags sequester ions from the pore solution, namely Ca2+ and SO42- ions forming an electrical double layer on the slag surface. Zeta potential measurements confirmed that different slags can exhibit different surface charges which can strongly affect PCE adsorption. The differences in the amounts of PCEs adsorbed result in different dosages required to achieve comparable dispersion. Generally, all slag cements tested required less PCE to achieve the same fluidity as with neat cement.
DOI:
10.14359/51688093
SP302-01
Joseph J. Assaad and Salim E. Asseily
The impact of clinker grinding aids (GAs) based on amine, glycol, or phenol on static yield stress (t0) of cement pastes is not well understood. Results obtained from this project have shown that GA molecules remain active after the grinding process and provide variations in cement properties, whether in the fresh or hardened states. Flowability improved and t0 decreased when the cement is ground using increased GA concentrations. This was attributed to the adsorption of these molecules onto the cement grains and saturation of surface charges, thus creating repulsive forces between neighboring particles. The decrease in t0 was particularly pronounced when phenol-based GA was used, given the presence of polycarboxylate polymers that help dispersing cement particles upon mixing with water.
10.14359/51688081
SP302-12
Lei Lei and Johann Plank
Polycarboxylate superplasticizers are known to be most powerful admixtures which exhibit superior dispersing force even at extremely low water-to-cement ratio. In this study, a simplified one-pot synthesis method for a PCE using only maleic anhydride and methoxy polyethylene glycol as sole raw materials was developed. Compared to conventional synthetic routes, the new method constitutes a much simpler process which performs esterification and grafting in one reactor. Macromonomers are no longer needed for the synthesis of this PCE. The resulting copolymer was characterized by size exclusion chromatography and anionic charge density measurement. Performance of the polymer in cement was probed via ‘mini slump test’. To detect a potential retarding effect of the copolymer, time-dependent heat evolution was monitored. Finally, a model for the formation of this PCE is proposed. According to this, maleic anhydride and MPEG maleate monoester are grafted onto MPEG macroradicals which present the backbone of this PCE.
10.14359/51688092
SP302-09
Yongwei Wang; Liya Wang; Yongsheng Liu; and Zepeng Chu
In this study, the polycarboxylate superplasticizers (PCs) with solid content up to 80% were synthetized using special redox initiator at 318K. In the radical polymerization reactions, combining with Fourier Transform Infrared Spectroscopy (FTIR) and Gel Permeation Chromatograph (GPC), the initiator dosing dosage, reaction temperature, reaction time and the concentration of system in the copolymerization reaction were systematic investigated through orthogonal design experiments. The performances of new PCs in cement paste were tested by measuring the fluidity and fluidity retention. The slump and the compressive strengths of concrete were also determined. Compared with traditional PC, the new PC has a better advantage in workability of fresh concrete and mechanical properties of hardened concrete.
10.14359/51688089
SP302-08
Shinji Tamaki; Kazuhide Saito; Kazuhisa Okada; Daiki Atarashi; and Etsuo Sakai
Several studies have been pursued in Japan on developing concrete using high volume blast-furnace slag cement for reducing CO2 emissions arising from calcination of cement. However, when using high volume blast-furnace slag cement, various problems are encountered, such as decreased fluidity retention ability caused by the reduction of admixture dosage and decreased strength enhancement. In this paper, the authors focus on the adsorption properties of polycarboxylate ether superplasticizers and the properties of hardened concrete that incorporates a component of high volume blast-furnace slag cement, and discuss the development of a new type of superplasticizer through molecular design and optimization of the admixture composition. The admixture improved the fluidity and properties of hardened concrete using slag cement containing more than 60% blast-furnace slag.
10.14359/51688088
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