Research on the Preparation and Properties of High Belite Sulphoaluminate Cement (HBSAC) Based on Various Industrial Solid Wastes

Su, Dunlei; Yue, Gongbing; Li, Qiuyi; Guo, Yuanxin; Gao, Song; Wang, Liang

doi:10.3390/ma12091510

Cited by 19 publications

(7 citation statements)

References 29 publications

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“…Meanwhile, at 1200 °C, the sulfur-fixation efficiency of adding Al 2 O 3 in clean coke continued to drop off quick with the increasing temperature. The phenomenon can be interpreted to start generating resistance to the high-temperature phase calcium sulfoaluminate (3CaO·3Al 2 O 3 ·CaSO 4 ) as temperature increased from 1100 to 1325 °C on the basis of the conventional sulfur-fixation product (CaSO 4 ) . However, when the combustion temperature is above 1200 °C, the sulfur-fixation rate always descends rapidly first and then increases slowly from 1200 to 1300 °C.…”

Section: Resultsmentioning

confidence: 99%

New Strategy toward Household Coal Combustion by Remarkably Reducing SO₂ Emission

et al. 2020

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A large amount of sulfur dioxide (SO2) will be released during rural household coal combustion, causing serious environmental pollution. Therefore, it is very urgent to develop a clean and efficient fuel to substitute rural household coal controlling SO2 emission. In this paper, a new strategy toward scattered coal combustion with remarkably reducing SO2 emission was proposed. Coal and compound additive of Al2O3 and CaCO3 were blended and then copyrolysis at 1050 °C was performed to produce clean coke. First, the sulfur content of clean coke was reduced, meanwhile, generating sulfur fixation precursor during pyrolysis. Then, clean coke is used for efficient sulfur fixation during the subsequent combustion process to reduce SO2 emissions. The effects of combustion temperature, Al/S molar ratio, and the mechanism of sulfur retention during clean coke combustion were studied in the tube furnace and muffle furnace. The mechanism can be attributed the following reason: (a) CaS produced during pyrolysis and CaO decomposed by complex additives were oxidized during combustion, and CaO captured the SO2 released from clean coke combustion, which formed CaSO4. (b) CaSO4 reacts with Al2O3 to produce calcium sulfoaluminate at high temperatures, which improves the sulfur fixation efficiency of clean coke combustion at high temperatures. In a word, this new strategy can greatly reduce the emission of SO2, thus helping to solve rural household coal pollution problems.

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Section: Resultsmentioning

confidence: 99%

New Strategy toward Household Coal Combustion by Remarkably Reducing SO₂ Emission

et al. 2020

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“…By controlling the alkalinity coefficient and adjusting the ratio of raw materials, as shown in Table 3 , the solid waste-based sulphoaluminate cement clinker was obtained after calcining at 1250 °C, and heating preservation time for 45 min [ 28 ]. Finally, 8% FGD gypsum was added to obtain the solid waste-based sulphoaluminate cement [ 29 ], after grinding and mixing, the solid waste-based sulphoaluminate cement was obtained. The compressive strength of solid waste-based sulphoaluminate cement prepared by different ratios were tested, respectively.…”

Section: Methodsmentioning

confidence: 99%

Preparation and Physico-Chemical Performance Optimization of Sintering-Free Lightweight Aggregates with High Proportions of Red Mud

et al. 2021

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Sintering-free lightweight aggregates were prepared with high proportions of red mud and a binder material derived from whole solid wastes through rolling granulation at room temperature. The preparation process was optimized by changing the material matching and size parameters of the SFLAs. The physico-chemical performance, including the density, mechanical strength, water absorption, hydration products, heavy metal leaching, and microstructure were evaluated by jointly employing X-ray Fluorescence, X-ray Diffraction, and Inductively Coupled Plasma Optical Emission Spectrometry, Shadow Electron Microscope, etc. The results indicated that the red mud and waste-based binders were highly compatible in the granulation process, with up to 80% red mud being successfully added. The sintering-free lightweight aggregates products at the binder content of 30% and the size coverage of 10–16 mm exhibited a bulk density of 900–1000 kg·m−3, a 28 d cylinder compressive strength of 9.2–11.3 MPa, and water absorption of less than 10%. Owing to the formation of important hydration products, ettringite, the heavy metal leaching of the sintering-free lightweight aggregates was also proven to be environmentally acceptable. This work provides a promising pathway to prepare low-cost, high-strength, and green lightweight aggregates through the large-scale utilization of solid waste red mud.

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“…The hydration rate of anhydrous calcium sulphoaluminate (C 4 A 3 S) is shown in Equation ( 4), and its hydration rate is extremely fast, which can make the 1 d strength of high-belite sulphoaluminate cement reach more than 85% of the final strength [31,34]. As can be seen from Figure 5, the content of hydrated calcium sulphoaluminate increases with the increase in nanosilica content at the same cement age, which also indicates that nanosilica can further promote the hydration process of anhydrous calcium sulphoaluminate (C 4 A 3 S).…”

Section: Xrd Analysismentioning

confidence: 99%

“…High-belite sulphoaluminate cement is a kind of green cement [30,31] that consumes less energy and emits less CO 2 in the preparation process. At the same time, properties such as quick setting and hardening, low hydration heat and excellent permeability resistance make high-belite sulphoaluminate cement widely useful in many fields, such as road rapid repair.…”

Section: Introductionmentioning

confidence: 99%

Study on the Influence of Nanosilica Sol on the Hydration Process of Different Kinds of Cement and Mortar Properties

Liu

et al. 2021

Materials

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Compared with nanosilica collected in a gaseous state, nanosilica sol has great economic value and application significance for improving the performance of concrete and mortar. In this study, the influence of nanosilica sol on the hydration process of different kinds of cement is studied by means of hydration heat analysis,X-ray diffraction analysis(XRD)and other methods, and the properties of mortar such as setting time, mechanical properties and porosity are also studied to characterize the influence of nanosilica sol on the macroscopic properties of mortar. The experimental results show that nanosilica sol can accelerate the hydration rate of two kinds of cement and promote the hydration reaction degree of cement, and this promotion effect increases with the increase in nanosilica sol content. At the same time, nanosilica sol can significantly shorten the setting time of the two kinds of cement, and it is more obvious with the increase in content. Excessive content of nanosilica sol will adversely affect the permeability resistance of mortar. It may be caused by the weak interval formed by nanosilica particle clusters in the mortar matrix, which can be supported by the mortar pore structure distribution test. At the same time, the influence of nanosilica sol on the hydration of the two kinds of cement is different, and the compressive strength of HBSAC cement mortar increases first and then decreases after adding nanosilica sol; However, the compressive strength of P·O 42.5 cement mortar increases gradually after adding nanometer silica sol. This shows that nanosilica sol does not effectively promote the hydration of β-C2S in high belite sulfoaluminate cement (HBSAC) mortar. Based on the above experimental results, it can be concluded that when the content of nanosilica sol is about 1%, it has the best promotion effect on the hydration of the two kinds of cement and the performance of mortar.

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Research on the Preparation and Properties of High Belite Sulphoaluminate Cement (HBSAC) Based on Various Industrial Solid Wastes

Cited by 19 publications

References 29 publications

New Strategy toward Household Coal Combustion by Remarkably Reducing SO₂ Emission

New Strategy toward Household Coal Combustion by Remarkably Reducing SO₂ Emission

Preparation and Physico-Chemical Performance Optimization of Sintering-Free Lightweight Aggregates with High Proportions of Red Mud

Study on the Influence of Nanosilica Sol on the Hydration Process of Different Kinds of Cement and Mortar Properties

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Research on the Preparation and Properties of High Belite Sulphoaluminate Cement (HBSAC) Based on Various Industrial Solid Wastes

Cited by 19 publications

References 29 publications

New Strategy toward Household Coal Combustion by Remarkably Reducing SO2 Emission

New Strategy toward Household Coal Combustion by Remarkably Reducing SO2 Emission

Preparation and Physico-Chemical Performance Optimization of Sintering-Free Lightweight Aggregates with High Proportions of Red Mud

Study on the Influence of Nanosilica Sol on the Hydration Process of Different Kinds of Cement and Mortar Properties

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New Strategy toward Household Coal Combustion by Remarkably Reducing SO₂ Emission

New Strategy toward Household Coal Combustion by Remarkably Reducing SO₂ Emission