Effect of slag cement on the properties of ultra-high performance concrete

•Slag cement is beneficial in the workability of fresh UHPC mixes.•Slag cement reduces the early-age strength but improves the later-age strength.•Slag cement increases the autogenous shrinkage in the steady stage.•Slag cement has inappreciable effect on the capillary absorption and salt scaling. Th...

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Bibliographic Details
Published in:Construction & building materials 2018-11, Vol.190, p.830-837
Main Authors: Liu, Zhichao, El-Tawil, Sherif, Hansen, Will, Wang, Fazhou
Format: Article
Language:English
Subjects:
Analysis
Building materials
Flowability
Freeze-thaw
Shrinkage deformation
Slag cement
UHPC
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Summary:•Slag cement is beneficial in the workability of fresh UHPC mixes.•Slag cement reduces the early-age strength but improves the later-age strength.•Slag cement increases the autogenous shrinkage in the steady stage.•Slag cement has inappreciable effect on the capillary absorption and salt scaling. This study investigates the effects of replacing a portion of Portland cement with slag cement (0%, 25%, 50% and 65% by mass) on the properties of plain ultra-high performance concrete (UHPC) mixes. It is observed that slag cement substantially enhances the flowability of the UHPC mixes and reduces the superplasticizer dosage. Mechanical properties are evaluated for mixes with similar air void characteristics, indicating that early age strength is reduced while there is more strength gain in the later age. This early age strength suppression is consistent with semi-adiabatic hydration heat evolution. The presence of slag cement reduces the maximum temperature rise. Linear deformation measurement on duplicate sealed specimens reveals four distinct stages for the shrinkage development and slag cement increases the shrinkage strain in the steady state, associated with the pozzolanic reaction. Simultaneous measurement of moisture uptake, mass loss and relative dynamic modulus of elasticity (RDM) on UHPC mixes for F-T durability shows that the cumulative moisture uptake and mass loss, when normalized with respect to the paste content, are almost negligible compared with a regular concrete mix. This reconciles the capillary suction dominated surface scaling mechanism. No internal bulk cracking is detected due to the dense matrix restricting the ingress of external moisture and the amount of freezable pore water.
ISSN:0950-0618
1879-0526
DOI:10.1016/j.conbuildmat.2018.09.173