Impact of condensed silica fume on splitting tensile strength and brittleness of high strength self‐compacting concrete

Self‐compacting concrete (SCC) is a type of concrete that can consolidate itself without external compaction. High‐strength SCC (HS‐SCC) is becoming more popular having a very broad range of application in Civil Engineering, such as piles, columns of tall buildings and piers for long‐span bridges. H...

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Published inStructural concrete : journal of the FIB Vol. 23; no. 1; pp. 604 - 618
Main Authors Wang, Qing, Yao, Boyu, He, Jianqiang, He, Xixi, Ho, J. C. M.
Format Journal Article
LanguageEnglish
Published Weinheim WILEY‐VCH Verlag GmbH & Co. KGaA 01.02.2022
Wiley Subscription Services, Inc
Subjects
Binders (materials)
Brittle fracture
Brittleness
Columns (structural)
Compressive strength
Concrete
condensed silica fume
microstructure
Piers
Self-compacting concrete
Silica fume
Silicon dioxide
Splitting
splitting tensile strength
Tall buildings
Tensile strength
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Summary:Self‐compacting concrete (SCC) is a type of concrete that can consolidate itself without external compaction. High‐strength SCC (HS‐SCC) is becoming more popular having a very broad range of application in Civil Engineering, such as piles, columns of tall buildings and piers for long‐span bridges. However, HS‐SCC is very brittle that limits its application above. To this, present study aims at mitigating the brittleness of HS‐SCC having a fixed water/binder ratio of 0.30 and binder content of 500 kg/m3 by blending cement with condensed silica fume (CSF). The percentage of CSF that replaced cement was 0–15% by weight. Apart from measuring the brittleness, mechanical property such as splitting tensile and compressive strength, as well as fresh property, such as slump flow, V‐funnel time, and L‐box passing ability was also obtained. The experimental results indicated that 10% replacement of cement by CSF could effectively decrease the brittleness of HS‐SCC and simultaneously increase the 28‐day compressive strength. On the other hand, the slump flow of concrete decreased as the content of CSF increased, but nonetheless was able to maintain at above 600 mm, which is a commonly accepted criteria for SCC. Lastly, scanning electron microscope figures showed that the microstructure of concrete and hydration morphology were enhanced by CSF particle.
Bibliography:Funding information
Discussion on this paper must be submitted within two months of the print publication. The discussion will then be published in print, along with the authors’ closure, if any, approximately nine months after the print publication.
Program for Innovative Research Team, Guangzhou Education Bureau, China, Grant/Award Number: 202032886; Guangzhou Science and Technology Plan, Grant/Award Number: 202002030166; Natural Science Foundation of China, Grant/Award Number: 52008120 52078147 52008118
ISSN:1464-4177
1751-7648
DOI:10.1002/suco.202000652