A platform for research: civil engineering, architecture and urbanism
A platform for research: civil engineering, architecture and urbanism
Properties and pore-forming mechanism of silica sand tailing-steel slag-coal gangue based permeable ceramics
https://orcid.org/0000-0002-3769-8102
https://orcid.org/0000-0002-5994-3949
Highlights Full solid waste system for preparing permeable ceramics. Systematic research on temperature and ratio to obtain excellent permeable ceramics. Different from the pore-forming mechanism of traditional permeable ceramics. Involves the formation of a glass liquid phase to explain the pore-forming mechanism.
Abstract In order to promote the construction of “sponge city”, fully utilize industrial solid waste, an eco-friendly permeable ceramic was successfully prepared by using silica sand tailing, steel slag and coal gangue. Through systematic investigation of water permeability, density, compressive strength, bending strength and chemical stability to study the effects of composition and sintering temperature changes on its properties. Its pore-forming mechanism was mainly researched by XRD, SEM and phase diagram analysis. Research indicates: As the content of silica sand tailing increases, the permeable ceramic structure becomes denser and the pores decrease. The best composition formula is silica sand tailing 55 wt%-steel slag 20 wt%-coal gangue 25 wt% (water permeability 4.68 × 10−2 cm/s, compressive strength 42.83 MPa, bending strength 6.87 MPa); with sintering temperature increasing, the permeable ceramic structure becomes porous, the optimum sintering temperature range is 1150 °C–1170 °C (water permeability 4.11 × 10−2 cm/s–4.96 × 10−2 cm/s, compressive strength 40.15 MPa–45.41 MPa, bending strength 6.26 MPa–7.88 MPa). Maintaining good chemical stability in both composition and sintering temperature change, and their permeability is far beyond the Chinese standard (1 × 10−2 cm/s). The pore formation is mainly attributed to the fact that the O2 released by the decomposition of Fe2O3 is coated by the formed glass liquid phase (Ca-Fe-Si-Mg-Al-O system) and flowing, then ruptures everywhere in the sample. This work maximizes the introduction of solid waste (100%), which not only protects the environment but also creates good economic benefits.
Properties and pore-forming mechanism of silica sand tailing-steel slag-coal gangue based permeable ceramics
https://orcid.org/0000-0002-3769-8102
https://orcid.org/0000-0002-5994-3949
Highlights Full solid waste system for preparing permeable ceramics. Systematic research on temperature and ratio to obtain excellent permeable ceramics. Different from the pore-forming mechanism of traditional permeable ceramics. Involves the formation of a glass liquid phase to explain the pore-forming mechanism.
Abstract In order to promote the construction of “sponge city”, fully utilize industrial solid waste, an eco-friendly permeable ceramic was successfully prepared by using silica sand tailing, steel slag and coal gangue. Through systematic investigation of water permeability, density, compressive strength, bending strength and chemical stability to study the effects of composition and sintering temperature changes on its properties. Its pore-forming mechanism was mainly researched by XRD, SEM and phase diagram analysis. Research indicates: As the content of silica sand tailing increases, the permeable ceramic structure becomes denser and the pores decrease. The best composition formula is silica sand tailing 55 wt%-steel slag 20 wt%-coal gangue 25 wt% (water permeability 4.68 × 10−2 cm/s, compressive strength 42.83 MPa, bending strength 6.87 MPa); with sintering temperature increasing, the permeable ceramic structure becomes porous, the optimum sintering temperature range is 1150 °C–1170 °C (water permeability 4.11 × 10−2 cm/s–4.96 × 10−2 cm/s, compressive strength 40.15 MPa–45.41 MPa, bending strength 6.26 MPa–7.88 MPa). Maintaining good chemical stability in both composition and sintering temperature change, and their permeability is far beyond the Chinese standard (1 × 10−2 cm/s). The pore formation is mainly attributed to the fact that the O2 released by the decomposition of Fe2O3 is coated by the formed glass liquid phase (Ca-Fe-Si-Mg-Al-O system) and flowing, then ruptures everywhere in the sample. This work maximizes the introduction of solid waste (100%), which not only protects the environment but also creates good economic benefits.
Properties and pore-forming mechanism of silica sand tailing-steel slag-coal gangue based permeable ceramics
https://orcid.org/0000-0002-3769-8102
https://orcid.org/0000-0002-5994-3949
Highlights Full solid waste system for preparing permeable ceramics. Systematic research on temperature and ratio to obtain excellent permeable ceramics. Different from the pore-forming mechanism of traditional permeable ceramics. Involves the formation of a glass liquid phase to explain the pore-forming mechanism.
Abstract In order to promote the construction of “sponge city”, fully utilize industrial solid waste, an eco-friendly permeable ceramic was successfully prepared by using silica sand tailing, steel slag and coal gangue. Through systematic investigation of water permeability, density, compressive strength, bending strength and chemical stability to study the effects of composition and sintering temperature changes on its properties. Its pore-forming mechanism was mainly researched by XRD, SEM and phase diagram analysis. Research indicates: As the content of silica sand tailing increases, the permeable ceramic structure becomes denser and the pores decrease. The best composition formula is silica sand tailing 55 wt%-steel slag 20 wt%-coal gangue 25 wt% (water permeability 4.68 × 10−2 cm/s, compressive strength 42.83 MPa, bending strength 6.87 MPa); with sintering temperature increasing, the permeable ceramic structure becomes porous, the optimum sintering temperature range is 1150 °C–1170 °C (water permeability 4.11 × 10−2 cm/s–4.96 × 10−2 cm/s, compressive strength 40.15 MPa–45.41 MPa, bending strength 6.26 MPa–7.88 MPa). Maintaining good chemical stability in both composition and sintering temperature change, and their permeability is far beyond the Chinese standard (1 × 10−2 cm/s). The pore formation is mainly attributed to the fact that the O2 released by the decomposition of Fe2O3 is coated by the formed glass liquid phase (Ca-Fe-Si-Mg-Al-O system) and flowing, then ruptures everywhere in the sample. This work maximizes the introduction of solid waste (100%), which not only protects the environment but also creates good economic benefits.
Properties and pore-forming mechanism of silica sand tailing-steel slag-coal gangue based permeable ceramics
Huang, Qianxing (author) / Liu, Taoyong (author) / Zhang, Jiashuo (author) / He, Xi (author) / Liu, Jianlei (author) / Luo, Zhiwei (author) / Lu, Anxian (author)
2020-03-23
Article (Journal)
Electronic Resource
English
Preparation method of modified coal gangue steel slag concrete
| European Patent Office | 2024
Steel slag-coal gangue geopolymer and preparation method thereof
| European Patent Office | 2021