A platform for research: civil engineering, architecture and urbanism
A platform for research: civil engineering, architecture and urbanism
Developing CO2-Sequstrating Strain-Hardening Magnesia-Based Composite (SHMC) with Hybrid Synthetic-Natural Fibers
Reactive magnesia cement (RMC) is an emerging green cement as it can sequestrate substantial CO2 to harden itself. However, the penetration of CO2 in RMC from outside to inside causes a change in microstructure with depth, which influences the fiber/matrix interface bond and fiber-bridging capacity. This work firstly investigated the influence of carbonation degree on interface bond by single fiber pull-out, SEM, FTIR and acid digestion tests, the results demonstrated that the interface bond is positively correlated to the carbonation degree, but high carbonation degree may induce the fiber rupture. Secondly, tensile test was conducted to explore the influence of carbonation degree on tensile performance, the results suggested increase in carbonation degree can significantly improve the tensile performance, and replacing partial PVA fiber with sisal fiber can prominently enhance the tensile performance at early stage. This work is the first time to clarify the relationship between carbonation degree, fiber/matrix interface bond and tensile performance of RMC, which may provide some guidance to the mix design and application of SHMC.
Developing CO2-Sequstrating Strain-Hardening Magnesia-Based Composite (SHMC) with Hybrid Synthetic-Natural Fibers
Reactive magnesia cement (RMC) is an emerging green cement as it can sequestrate substantial CO2 to harden itself. However, the penetration of CO2 in RMC from outside to inside causes a change in microstructure with depth, which influences the fiber/matrix interface bond and fiber-bridging capacity. This work firstly investigated the influence of carbonation degree on interface bond by single fiber pull-out, SEM, FTIR and acid digestion tests, the results demonstrated that the interface bond is positively correlated to the carbonation degree, but high carbonation degree may induce the fiber rupture. Secondly, tensile test was conducted to explore the influence of carbonation degree on tensile performance, the results suggested increase in carbonation degree can significantly improve the tensile performance, and replacing partial PVA fiber with sisal fiber can prominently enhance the tensile performance at early stage. This work is the first time to clarify the relationship between carbonation degree, fiber/matrix interface bond and tensile performance of RMC, which may provide some guidance to the mix design and application of SHMC.
Developing CO2-Sequstrating Strain-Hardening Magnesia-Based Composite (SHMC) with Hybrid Synthetic-Natural Fibers
RILEM Bookseries
Kunieda, Minoru (editor) / Kanakubo, Toshiyuki (editor) / Kanda, Tetsushi (editor) / Kobayashi, Koichi (editor) / Wu, Bo (author) / Su, Xianjun (author) / Qiu, Jishen (author)
International Conference on Strain-Hardening Cement-Based Composites ; 2022
2023-02-01
10 pages
Article/Chapter (Book)
Electronic Resource
English
Fire resistance of strain hardening cementitious composite with hybrid PVA and steel fibers
| British Library Online Contents | 2017
Fire resistance of strain hardening cementitious composite with hybrid PVA and steel fibers
| Online Contents | 2017