Your search keyword '"Yishun, Liao"' showing total 11 results

1. Effect of calcium nitrate on hydration properties and strength development of calcium sulfoaluminate cement

Author

Zhuo, Chen, Yishun, Liao, Fang, Deng, Kejin, Wang, Tianxiao, Zhang, Haibao, Wang, Huachen, Liu, Seth, Silupumbwe, and Shengwen, Tang

Published

2024

2. A study on the hydration of calcium aluminate cement pastes containing silica fume using non-contact electrical resistivity measurement

Author

Yishun Liao, Sichun Wang, Kejin Wang, Siraj Al Qunaynah, Shihui Wan, Zhengxia Yuan, Pengfei Xu, and Shengwen Tang

Subjects

Calcium aluminate cement, Silica fume, Electrical resistivity, Hydration products, Conversion, Reaction mechanism, Mining engineering. Metallurgy, TN1-997

Abstract

In this study, a non-contact electrical resistivity method is employed to investigate the hydration process of calcium aluminate cement (CAC) pastes incorporating silica fume (SF) at an early age. The CAC-SF pastes have a water-to-binder ratio (w/b) of 0.6 and a replacement of SF for CAC at 0, 5, 10, and 20% (by weight of the binder). The pastes are tested for electrical resistivity, thermal analysis (internal temperature), setting time, and compressive strength, and the hydration products of the pastes are also examined. The results indicate that the evolution of electrical resistivity is closely related to the hydration process of the CAC pastes, and the conversion stage is closely associated with the setting time of pastes. As the increase of SF replacement, the hydration process of CAC pastes was accelerated within 24 h, and the development of compressive strength was hampered at an early age but increased later. SF replacement inhibits the conversion of metastable CAC hydrates (CAH10 and C2AH8) to C3AH6 through filling, seeding, and reacting with CAC, thus reducing the heat of hydration.

Published

2023

3. Influence of cement on properties of calcined phosphogypsum based composite cementitious materials

Author

Fang Deng, Jian Ye, Yanling Liu, Tianxiao Zhang, Yishun Liao, and Shengwen Tang

Subjects

Calcined phosphogypsum, Cement, Deterioration coefficient, Hydration heat, Heavy metal leaching, Compressive strength, Mining engineering. Metallurgy, TN1-997

Abstract

Phosphogypsum is an industrial waste generated in the production of fertilizers causing environmental problems. Calcined phosphogypsum (CPG) is obtained by low-temperature calcination and dehydration of phosphogypsum. CPG is mainly used to produce building materials. However, mechanical strength properties and water resistance of CPG materials is extremely poor, which leads to its relatively low utilization rate in construction industry. To address this issue, various amount of Ordinary Portland cement (OPC), fly ash (FA), rice husk (RH) and modified admixtures (AD) were mixed with the CPG to obtain CPG-based composite cementitious materials, which enhanced the water resistance and mechanical strength of the corresponding hardened materials. The influence of different contents of cement on the setting time, hydration heat, hydration products, mechanical properties, water absorption, heavy metal leaching and deterioration coefficient of the composite cementitious material is investigated. The results showed that the optimal mixing ratio of CPG: OPC: FA: RH was 57: 20: 10: 13 considering the water resistance and mechanical strength properties of CPG-based composite cementitious materials. On these conditions, the compressive strength, the flexural strength, water absorption and deterioration coefficient of the specimens at 28 days are 6.1 MPa, 4.6 MPa, 29.4% and 0.66 respectively, which were in line with the national standard of phosphorus building gypsum wallboard. It was demonstrated that two skeleton types are present in the samples prepared using CPG-based composite cementitious materials, which had a synergistic support effect on the structure. The first skeleton was formed by gypsum dihydrate crystals (CaSO4·2H2O) and provided strength to the specimens at an early stage, while the second skeleton was formed by ettringite (AFt) and C–S–H gels, which provided strength at a later stage. The skeletons make the hardened materials denser and more waterproof. Moreover, the composite materials exhibited a positive solidification effect on heavy metals present in CPG.

Published

2023

4. Effect of Calcium Nitrate on Hydration Properties and Strength Development of Calcium Sulfoaluminate Cement

Author

Zhuo Chen, Yishun LIAO, Fang Deng, Kejin Wang, Tianxiao Zhang, Haibao Wang, Huachen Liu, Seth Silupumbwe, and Shengwen Tang

Published

2023

5. Hydration Characteristics of Supersulfated Cement Made with Calcined Phosphogypsum and Slaked Lime

Author

Yishun LIAO, Jinxin Yao, Fang Deng, Hao Li, Kejin Wang, Huizhen Yang, and Shengwen Tang

Published

2023

6. Activation energy of calcium sulfoaluminate cement-based materials

Author

Shengwen Tang, Samaila Muazu Bawa, Yu Gui, Yishun Liao, Kejin Wang, and Siraj Al Qunaynah

Subjects

Cement, Calcium sulfoaluminate, Materials science, Silica fume, Analytical chemistry, Building and Construction, Activation energy, Type (model theory), law.invention, Portland cement, Mechanics of Materials, law, Fly ash, General Materials Science, Civil and Structural Engineering, Shrinkage

Abstract

In this study, calcium sulfoaluminate (CSA) cement pastes were tested for heat of hydration and chemical shrinkage at temperatures of 20 °C, 30 °C and 40 °C. Apparent activation energy ( $$E_{a}$$ ) values were then calculated using both exponential and hyperbolic methods. The average $$E_{a}$$ of the CSA cements ranged from 42.24 to 80.22 kJ/mol, much higher than that of Type I Portland cement (38–45 kJ/mol). $${E}_{a}$$ increased slightly with the replacement of silica fume for cement. However, average $${E}_{a}$$ decreased by 18.4% when 20% Class C fly ash was used, but increased by 21.3% when 40% Class C fly ash was used. $$E_{a}$$ calculated from heat of hydration using the exponential method is 17% lower than that obtained using the hyperbolic method. When the exponential method was used, $${E}_{a}$$ values determined using heat of hydration were 30% higher than those obtained using chemical shrinkage.

Published

2021

7. Effect of steel slag on the hydration and strength development of calcium sulfoaluminate cement

Author

Guoxi Jiang, Siraj Al Qunaynah, Kejin Wang, Yishun Liao, and Wenjie Yuan

Subjects

Cement, Ettringite, Materials science, Calcium sulfoaluminate, Metallurgy, 0211 other engineering and technologies, 020101 civil engineering, 02 engineering and technology, Building and Construction, 0201 civil engineering, Dilution, chemistry.chemical_compound, Compressive strength, chemistry, Electrical resistivity and conductivity, 021105 building & construction, Bound water, General Materials Science, Civil and Structural Engineering, Shrinkage

Abstract

In this study, effects of steel slag on the hydration and strength development of calcium sulfoaluminate (CSA) cement were investigated. Pastes with 0%, 10%, 20%, and 40% (by mass) of steel slag replacements for CSA cement were tested for setting time, chemical shrinkage, electrical resistivity, and compressive strength. The hydration products, bound water content, pore structure, and pH value of the pore solutions of these pastes were also analyzed. The results indicate that at early ages (from 2 h to 28 d), steel slag worked like a filler and had a dilution effect on CSA cement hydration. Therefore, setting time increased and chemical shrinkage, electrical resistivity, chemically bound water content, and compressive strength of the pastes reduced with increase of steel slag replacements. But, at late ages (≥90 days), these properties in pastes with steel slag replacements surpassed those of the plain CSA cement paste due to hydration of steel slag, which increased pH values of pore solutions and subsequently stabilized ettringite in the pastes. Steel slag replacement for CSA cement also accelerated stratlingite formation. Both ettringite stabilization and stratlingite formation appeared to be the primary mechanisms for strength compensation of CSA cement paste at late ages.

Published

2020

8. Relationship between Chemical Shrinkage and Electrical Resistivity for Cement Pastes at Early Age

Author

Yishun Liao and Xiaosheng Wei

Subjects

Cement, Materials science, Water–cement ratio, Building and Construction, Test method, Cement paste, Degree (temperature), law.invention, Portland cement, Mechanics of Materials, Electrical resistivity and conductivity, law, General Materials Science, Composite material, Civil and Structural Engineering, Shrinkage

Abstract

The objective of this paper is to investigate the relationship between the chemical shrinkage and electrical resistivity of portland cement pastes during the first 3 days. Plain cement pastes with water to cement (W/C) ratios 0.3, 0.4, and 0.5 were used in this paper. Chemical shrinkage was measured by dilatometry according to industry standards for test methods for chemical shrinkage of hydraulic cement paste. Electrical resistivity was measured by a noncontacting electrical resistivity apparatus. The relationship between electrical resistivity and degree of hydration was investigated. The results obtained show that the relationship between chemical shrinkage and electrical resistivity appears to be roughly linear after 12 h. Note that the electrical resistivity after 12 h can be used to determine the chemical shrinkage and degree of hydration.

Published

2014

9. Penetration resistance and electrical resistivity of cement paste with superplasticizer

Author

Xiaosheng Wei and Yishun Liao

Subjects

Cement, Vicat softening point, Materials science, Superplasticizer, Building and Construction, Penetration (firestop), Cement paste, law.invention, Portland cement, Compressive strength, Mechanics of Materials, law, Electrical resistivity and conductivity, General Materials Science, Composite material, Civil and Structural Engineering

Abstract

The purpose of this paper is to investigate the setting process and evolution of electrical resistivity of Portland cement pastes with constant water to cement ratio (w/c) of 0.3 and with different dosages of naphthalene superplasticizer (SP) from 0 to 1.2 %. The setting process of cement paste was monitored by the Vicat needle test. The depth of penetration was recorded and used to calculate the shear resistance generated by the cement paste. Electrical resistivity was measured by a non-contacting electrical resistivity apparatus. The hyperbolic curve of electrical resistivity versus time was plotted to determine the ultimate electrical resistivity. The results show that the addition of SP to the pastes with a fixed w/c can cause longer setting time and delay the evolution of electrical resistivity. The final setting time (tf) and the occurring time of maximum rate of electrical resistivity (tr) were both delayed when the dosage of SP was increased. This may indicates that the electrical resistivity measurement can be used to monitor the setting process of cement. The compressive strength at 28 days and the ultimate electrical resistivity show a same tendency for the cement pastes with different dosages of SP. Thus, it would be possible to predict the compressive strength of hardened cement paste by its ultimate electrical resistivity.

Published

2013

10. Early hydration of calcium sulfoaluminate cement through electrical resistivity measurement and microstructure investigations

Author

Yishun Liao, Li Guowei, and Xiaosheng Wei

Subjects

Cement, Ettringite, Gypsum, Materials science, Metallurgy, Building and Construction, engineering.material, Microstructure, Ion, chemistry.chemical_compound, Compressive strength, chemistry, Electrical resistivity and conductivity, engineering, General Materials Science, Composite material, Porosity, Civil and Structural Engineering

Abstract

The electrical resistivities of the calcium sulfoaluminate (CSA) cement pastes at different water to cement (W/C) ratios, over a period of 1440 min (or 24 h) were measured by a non-contacting electrical resistivity apparatus. The electrical resistivity–time curve decreased slightly after mixing, and then increased sharply around the setting time, followed by two peaks, and finally developed at a very low rate up to 1440 min. The porosity plays a dominant role in the electrical resistivity development of the CSA cement paste in the earlier period of hydration (before the initial setting time), while the ion concentration plays a major role at the later period (after the second peak). The electrical resistivity–time curve demonstrates the process of ettringite formation and transformation to monosulfate in the CSA hydration system, and this is confirmed by the SEM and XRD observations. The high temperature and the insufficiency of gypsum in the CSA cement system during hydration result in the decomposition of ettringite at the first peak, while at the second peak the decomposition of ettringite is due to the lack of gypsum. The relationship between W/C and electrical resistivity at 1 h follows a negative trend but a positive trend is observed at 24 h. The relationship between the compressive strength and the electrical resistivity at 24 h for the different W/C ratios follows a negative relationship.

Published

2011

11. Early age properties of cementitious materials by electrical resistivity measurement

Author

Xiaosheng Wei, Lianzhen Xiao, and Yishun Liao

Subjects

Cement, Thermogravimetric analysis, Compressive strength, Materials science, Electrical resistivity and conductivity, Fly ash, General Materials Science, Cementitious, Composite material, Water content, Dilution

Abstract

Three cement pastes were prepared with the fixed water-binder ratio and different fly ash contents. The compression test and electrical resistivity measurement of the paste mixes were conducted during 48 h. The changes of the CH content and the non-evaporable water content in the cement-fly ash hydration systems with time were obtained by the thermal gravimetric analysis. The experimental results show that dilution effect of fly ash as micro-filler is dominant mechanism before 48 h, which appears to decrease in the CH content and the non-evaporable water content, also in compressive strength and electrical resistivity, with the increase of fly ash replacement. The relationships between CH content, non-evaporable water content and electrical resistivity show that electrical resistivity can be the indicators of hydration products CH and non-evaporable water. The correlation of the compressive strength fc and the electrical resistivity ρ can be obtained as fc=8.3429 ρ = 6.7088 for the period of 48 h. The early age compressive strength can then be predicted by electrical resistivity measurement.

Published

2010