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A platform for research: civil engineering, architecture and urbanism
Characterization of magnesium-calcium oxysulfate cement prepared by replacing MgSO4 in magnesium oxysulfate cement with untreated desulfurization gypsum
https://orcid.org/0000-0003-3372-3101
https://orcid.org/0000-0003-2862-3392
Abstract A new magnesium-calcium oxysulfate cement (MCOSC) was proposed by replacing MgSO4 in magnesium oxysulfate cement (MOSC) with untreated flue gas desulfurization gypsum (FGDG) at levels of 25%, 50%, 75% and 100%. The synergistic effect of FGDG and chemical additives, including citric acid, ammonium citrate tribasic and ammonium dihydrogen phosphate on the mechanical performance and hydration mechanism of MCOSC was investigated. The results showed that three additives all promoted the formation of 5 Mg(OH)2·MgSO4·7H2O (5·1·7) phase and hindered Mg(OH)2 precipitation, improving mechanical properties of MCOSC. FGDG incorporation induced no new crystalline phase, but gypsum crystal provided the space for nucleation of 5·1·7 phase. FGDG also reacted with MOSC to form amorphous phase, which was identified as a magnesium-sulfide-calcium-hydrate gel. Moreover, it affected the morphology of 5·1·7 phase and lowered the temperature of endothermic peaks in the paste during the heating process. The additive-incorporated specimens with 25% FGDG replacement presented a superior compressive strength, water resistance and volume stability. This confirmed the effective application of FGDG in preparing MCOSC, and it also provided an approach for recycling waste gypsum.
Highlights Magnesium-calcium oxysulfate cement is prepared by replacing MgSO4 with untreated FGDG. The synergistic effect of FGDG and additives on mechanical performance and hydration mechanism of MCOSC is studied. CA, ACT and ADP all induce the formation of needle-like 5·1·7 phase. FGDG provides the space for nucleation of 5·1·7 phase and reacts to form a magnesium-sulfide-calcium-hydrate gel.
Characterization of magnesium-calcium oxysulfate cement prepared by replacing MgSO4 in magnesium oxysulfate cement with untreated desulfurization gypsum
https://orcid.org/0000-0003-3372-3101
https://orcid.org/0000-0003-2862-3392
Abstract A new magnesium-calcium oxysulfate cement (MCOSC) was proposed by replacing MgSO4 in magnesium oxysulfate cement (MOSC) with untreated flue gas desulfurization gypsum (FGDG) at levels of 25%, 50%, 75% and 100%. The synergistic effect of FGDG and chemical additives, including citric acid, ammonium citrate tribasic and ammonium dihydrogen phosphate on the mechanical performance and hydration mechanism of MCOSC was investigated. The results showed that three additives all promoted the formation of 5 Mg(OH)2·MgSO4·7H2O (5·1·7) phase and hindered Mg(OH)2 precipitation, improving mechanical properties of MCOSC. FGDG incorporation induced no new crystalline phase, but gypsum crystal provided the space for nucleation of 5·1·7 phase. FGDG also reacted with MOSC to form amorphous phase, which was identified as a magnesium-sulfide-calcium-hydrate gel. Moreover, it affected the morphology of 5·1·7 phase and lowered the temperature of endothermic peaks in the paste during the heating process. The additive-incorporated specimens with 25% FGDG replacement presented a superior compressive strength, water resistance and volume stability. This confirmed the effective application of FGDG in preparing MCOSC, and it also provided an approach for recycling waste gypsum.
Highlights Magnesium-calcium oxysulfate cement is prepared by replacing MgSO4 with untreated FGDG. The synergistic effect of FGDG and additives on mechanical performance and hydration mechanism of MCOSC is studied. CA, ACT and ADP all induce the formation of needle-like 5·1·7 phase. FGDG provides the space for nucleation of 5·1·7 phase and reacts to form a magnesium-sulfide-calcium-hydrate gel.
Characterization of magnesium-calcium oxysulfate cement prepared by replacing MgSO4 in magnesium oxysulfate cement with untreated desulfurization gypsum
https://orcid.org/0000-0003-3372-3101
https://orcid.org/0000-0003-2862-3392
Abstract A new magnesium-calcium oxysulfate cement (MCOSC) was proposed by replacing MgSO4 in magnesium oxysulfate cement (MOSC) with untreated flue gas desulfurization gypsum (FGDG) at levels of 25%, 50%, 75% and 100%. The synergistic effect of FGDG and chemical additives, including citric acid, ammonium citrate tribasic and ammonium dihydrogen phosphate on the mechanical performance and hydration mechanism of MCOSC was investigated. The results showed that three additives all promoted the formation of 5 Mg(OH)2·MgSO4·7H2O (5·1·7) phase and hindered Mg(OH)2 precipitation, improving mechanical properties of MCOSC. FGDG incorporation induced no new crystalline phase, but gypsum crystal provided the space for nucleation of 5·1·7 phase. FGDG also reacted with MOSC to form amorphous phase, which was identified as a magnesium-sulfide-calcium-hydrate gel. Moreover, it affected the morphology of 5·1·7 phase and lowered the temperature of endothermic peaks in the paste during the heating process. The additive-incorporated specimens with 25% FGDG replacement presented a superior compressive strength, water resistance and volume stability. This confirmed the effective application of FGDG in preparing MCOSC, and it also provided an approach for recycling waste gypsum.
Highlights Magnesium-calcium oxysulfate cement is prepared by replacing MgSO4 with untreated FGDG. The synergistic effect of FGDG and additives on mechanical performance and hydration mechanism of MCOSC is studied. CA, ACT and ADP all induce the formation of needle-like 5·1·7 phase. FGDG provides the space for nucleation of 5·1·7 phase and reacts to form a magnesium-sulfide-calcium-hydrate gel.
Characterization of magnesium-calcium oxysulfate cement prepared by replacing MgSO4 in magnesium oxysulfate cement with untreated desulfurization gypsum
Gu, Kang (author) / Chen, Bing (author) / Yu, Hongfa (author) / Zhang, Na (author) / Bi, Wanli (author) / Guan, Yan (author)
2021-05-04
Article (Journal)
Electronic Resource
English
| European Patent Office | 2023
Strength development in magnesium oxysulfate cement
| Elsevier | 1977