Abstract
The use of saturated coral aggregate (SCA) as practical replacement of quartz sand has been shown to effectively mitigate the autogenous shrinkage in ultrahigh performance concrete (UHPC). The autogenous deformation, the compressive strength, the flexural strength, and the hydration property development of paste with different shrinkage means were tested. Three different methods were evaluated to mitigate the autogenous shrinkage: SCA, shrinkage reducing admixture (SRA), and the mixture of SCA and SRA (SRA-SCA). It was found that SCA and SRA have all the effective ways to reduce the shrinkage deformation, and SRA-SCA was the most effective in mitigating the shrinkage. The autogenous shrinkage of UHPC was restrained, when the SCA dosage was 44%, the SRA dosage was 0.8%, the SCA content was 26%, the SRA dosage was 2.4%, the SCA content was 18%, the SRA content was 2.4%, or the SCA dosage was 26%. The mechanical properties were deteriorated by the addition of SCA, while the compressive strength was still higher than 90 MPa at 28 days even though the replacement ratio of SCA was up to 50%. Furthermore, internal curing by means of SCA was proved to be a successful way to mitigate autogenous shrinkage, after the tests.
Highlights
The application of ultrahigh performance concrete (UHPC) has been developed in more and more engineering, because of high compressive strength, high tensile strength, high ductility, and high density
The homogeneity was changed as the porous saturated coral aggregate (SCA) was added to UHPC, and the extremely compacting structure was broken with more shrinkage reducing admixture (SRA) or higher water to binder ratio (W/B)
When the SRA content was 0.8%, the compressive strength of samples decreased with increasing SCA compared with reference S7
Summary
The application of UHPC has been developed in more and more engineering, because of high compressive strength (over 100 MPa), high tensile strength (over 8 MPa), high ductility, and high density. UHPC overcomes the normal concrete drawback; the increase of strength is accompanied by higher brittleness [1, 2]. These outstanding properties are attributed to the high binder content, the high ultrafine powder content, and the low water to binder ratio (W/B). Due to the low W/B (usually lower than 0.2) and high silica components content, the hydration heat of UHPC is high, and the internal relative humidity decreased quickly. These hydration reactions caused the high earlyage autogenous shrinkage and shrinkage cracking. The durability will get worse and worse, and the service life will shorten strongly [3]
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