Publication: Effect of water-reducing admixtures having hybrid silicon air-entraining surfactants on some properties of concrete mixtures
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Date
2022-09-01
Authors
Emin, Ayvaz
Authors
Emin, Ayvaz
Özen, Süleyman
Mardani-Ağhabağlou, Ali
Ünlu, Ayda
Kapti, Tolga
Journal Title
Journal ISSN
Volume Title
Publisher
Asce-Amer Soc Civil Engineers
Abstract
In order to improve the fresh properties and freeze-thaw resistance of cementitious systems, water-reducing and air-entraining admixtures are actively used in concrete mixtures. Generally, these mentioned admixtures are added to concrete mixtures as two separate admixtures. In this case, when the properties/compositions of one of the admixtures change, compatibility problems of admixtures may occur with each other or with the cement, and the fresh/hardened properties of the concrete may be adversely affected. In this study, a modified water-reducing admixture with both fluidity and air-entraining properties was produced. The utilization effect of high-range water-reducing admixtures (HRWR) having different ethylene oxide/propylene oxide (EO/PO)-based air-entraining surfactants (AES) on some properties of concrete mixtures was investigated. For this purpose, firstly, hybrid silicone AESs with a silicon content of 20%, 33%, and 38.5% were supplied. Then, HRWRs containing seven different AES were produced by using substitution and synthesis methods. In HRWRs produced by the substitution method, 3 and 5 wt. % of HRWR were substituted with EO/PO-based hybrid silicon AES. In the other method, EO/PO-based hybrid silicon air-entraining macromonomers were bonded to the HRWR at ratios of 1, 3, and 5 wt. % during its synthesis process. Replacing HRWR with hybrid silicone AESs increased admixture demand to provide the target slump value in concrete mixtures. Utilization of AESs containing 20% and 33% silicon in HRWR by the substitution method positively affected the permeability and compressive strength of concrete mixtures, while the rise of this ratio to 38.5% by using the synthesis method did not affect them significantly. The presence of surfactant with 20% silicon in 3% and 5% of the admixture and with 33% silicon in 5% of the admixture positively affected frost resistance of concrete mixtures. However, the use of surfactants with 33% silicon content in 3% of the admixture and 38.5% silicon in 1%, 3%, and 5% of the admixture showed a negative effect on the frost resistance of the mixtures.
Description
Keywords
Freeze-thaw resistance, Polycarboxylate superplasticizers, Transport-properties, Cement, Performance, Compatibility, Hydration, Behavior, Mortar, Agent, Air entraining surfactant (aes), Ethylene, Propylene oxide, Water reducing admixture, Permeability, Freezing thawing, Construction & building technology, Engineering, Materials science