Characterization of Ultrahigh-Performance Concrete Materials for Application in Modular Construction

AbstractIn this paper, a new class of self-consolidating ultrahigh-performance concrete (UHPC) was investigated. The UHPC featured a compressive strength higher than 150 MPa with self-consolidating characteristics desirable for modular construction. This paper describes the development and character...

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Bibliographic Details
Published in:Journal of materials in civil engineering 2021-05, Vol.33 (5)
Main Authors: Lim, Ing, Sawab, Jamshaid, Wang, Jiaji, Fan, Shuai, Mo, Y. L, Li, Mo
Format: Article
Language:English
Subjects:
Building materials
Civil engineering
Compressive strength
Concrete
Consolidation
Construction & Building Technology
Engineering
Hydration
Materials Science
Microstructure
Modular construction
Mortars (material)
Packing density
Particle beams
Particle size distribution
Physical properties
Silica fume
Silicon dioxide
Steel plates
Technical Papers
Ultra high performance concrete
X ray microtomography
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Summary:AbstractIn this paper, a new class of self-consolidating ultrahigh-performance concrete (UHPC) was investigated. The UHPC featured a compressive strength higher than 150 MPa with self-consolidating characteristics desirable for modular construction. This paper describes the development and characterization of UHPC, its large-scale processing techniques with conventional equipment, its verification with internal and surface microstructure analysis techniques, and the structural behavior of large-scale steel plate UHPC (S-UHPC) beams under out-of-plane loads. Based on a particle size distribution study, an optimum packing density was achieved in the mixture that uses an uncommonly used undensified silica fume. The physical parameters of the ingredients and the resulting microstructure after hydration are considered essential for the design of self-consolidating UHPC materials. Distinguishing the three phases of the material after hydration using three-dimensional X-ray microtomography allowed the quantitative analysis of the UHPC microstructure. The internal microstructure study showed a significant reduction of macropores in UHPC compared to mortar specimens, which confirmed the physical attributes behind the improved material characteristics. A microstructure study of the material was also performed using scanning electron microscopy. In addition, a comparison of the experimental results of four large-scale steel plate concrete (SC) beam specimens cast with either conventional concrete or UHPC materials under three-point shear loading indicated that the developed UHPC materials significantly enhanced the ductility and capacity of the S-UHPC beams.
ISSN:0899-1561
1943-5533
DOI:10.1061/(ASCE)MT.1943-5533.0003674