Design of Rapid Hardening Quaternary Zeolite-Containing Portland-Composite Cements

Myroslav Sanytsky; Tetiana Kropyvnytska; Taras Kruts; Oleksander Horpynko; Iryna Geviuk

doi:10.4028/www.scientific.net/KEM.761.193

Paper Titles

Influence of Various Amount of Steel Fibers on Load Capacity and Strain in Model Foundation Slab
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NTCC 2017: Long-Term Observation of the Resistance of Novel Hybrid Cement Exposed to Sulphate Solution
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Assessment of Fiber Reinforced Concrete Slab and Subsoil Interaction - Experiment
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Preliminary Study of the Use of a Secondary Lead Smelting Slag as an Addition to Portland Cement
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Development of Sustainable Alternative Building Materials from Quarry Dust
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Phytotoxicity Analysis of Different Compositions of Nanostructured Binder
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Design of Rapid Hardening Quaternary Zeolite-Containing Portland-Composite Cements
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Life Cycle Assessment of Natural Fibre Reinforced Cementitious Composites
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HomeKey Engineering MaterialsKey Engineering Materials Vol. 761Design of Rapid Hardening Quaternary...

Design of Rapid Hardening Quaternary Zeolite-Containing Portland-Composite Cements

Abstract:

The strength development of a quaternary Portland cement composite system containing blast-furnace slag, zeolitic tuff and limestone powder is presented. The composition and particle size distribution of the constituents are optimized by the incremental coefficient of the surface activity of the zeolite-containing Portland composite cements. Zeolitic tuff and limestone powder of high specific surface area lead to the increase of the surface activity of the entire system and a corresponding improvement in the performance of the cement.

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Periodical:

Key Engineering Materials (Volume 761)

Pages:

193-196

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.761.193

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Online since:

January 2018

Authors:

Myroslav Sanytsky*, Tetiana Kropyvnytska, Taras Kruts, Oleksander Horpynko, Iryna Geviuk

Keywords:

Cement Manufacture, Experimental Design, Non-Clinker Constituent, Particle Size Distribution, Quaternary Portland-Composite Cement, Sustainability Manufacture

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