Recent advances in heighten sulfur resistance of SCR catalysts: A review

Zhao, Ling; Zhang, Yu; Kang, Myounggu

doi:10.4491/eer.2020.642

Cited by 11 publications

(4 citation statements)

References 65 publications

(66 reference statements)

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“…The reasons could be explained by the change in rheological characteristics of the asphaltenes contained in RMG. Asphaltenes, which have a highly complex molecular structure, readily dissolve in aromatic compounds but do not dissolve in paraffin [7]. As asphaltenes in fuel oil stabilize in micellar form upon adsorption by resin [37,38], the saturation rate of aromatics that can dissolve the micelles is the critical parameter for stabilizing the asphaltenes [39].…”

Section: Dispersion Stabilitymentioning

confidence: 99%

“…The demand for VLSFO is expected to continue over the long term, as the adoption possibility of future regulations governing scrubber wash-water cannot be ruled out. Moreover, using VLSFO may also be beneficial in improving the efficiency of selective catalytic reduction [6], the only method of NO X emission reduction recognized by the IMO, as denitrification catalysts can be easily contaminated by SO 2 [7] and suffer from operational problems, such as sulfuric acid corrosion [8].…”

Section: Introductionmentioning

confidence: 99%

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Effect of Ultrasound Irradiation on the Properties and Sulfur Contents of Blended Very Low-Sulfur Fuel Oil (VLSFO)

Jeon

2022

JMSE

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Quality issues concerning very low-sulfur fuel oil (VLSFO) have increased significantly since the IMO sulfur-limit regulation became mandatory in 2020, as most VLSFO is produced by blending high-sulfur fuel oil (HSFO) with VLSFO. For instance, the conversion of VLSFO paraffins (C19 or higher alkanes) into waxes at low temperatures adversely affects cold flow properties. This study investigates the effects of ultrasonication on the chemical composition, dispersion stability, and sulfur content of samples prepared by blending ISO-F-DMA-grade marine gas oil (i.e., VLSFO) and ISO-F-RMG-grade marine heavy oil (i.e., HSFO) in volumetric ratios of 25:75 (BFO1), 50:50 (BFO2), and 75:25 (BFO3). The paraffin content decreased by 19.2% after 120 min of ultrasonic irradiation for BFO1 by 16.8% after 30 min for BFO3. The decrease in the content of high-molecular-weight compounds was faster at higher HSFO content; however, ultrasonication for longer-than-optimal times induced reaggregation, and thus, increased the content of high-molecular-weight compounds and decreased dispersion stability. In addition, ultrasonication did not significantly affect the sulfur content of BFO1 but decreased those of BFO2 (by 19% after 60 min) and BFO3 (by 25% after 30 min). Desulfurization efficiency increased with the increasing content of HSFO, as water present therein acted as an oxidant for oxidative desulfurization.

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Section: Dispersion Stabilitymentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Effect of Ultrasound Irradiation on the Properties and Sulfur Contents of Blended Very Low-Sulfur Fuel Oil (VLSFO)

Jeon

2022

JMSE

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“…This method has high deoxygenation efficiency (up to 80–90%) and high technology maturity. As the core of the technology, the SCR catalyst constitutes approximately 30–50% of the total de-NO x system investment. , Due to the complex flue gas environment, the SCR catalyst will be poisoned during long-term use, which results in a reduction in specific catalytic activity and affects its denitration efficiency. − Generally, the service life of denitration catalysts is three to five years, depending on the composition of the flue gas and the type of combustion system . The use of SCR technology is increasing, and the catalysts abandoned by denitration units have gradually become problematic.…”

Section: Introductionmentioning

confidence: 99%

Strategy and Technical Progress of Recycling of Spent Vanadium–Titanium-Based Selective Catalytic Reduction Catalysts

Zhao,

Zhang,

Yang

et al. 2024

ACS Omega

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Selective catalytic reduction denitration technology, abbreviated as SCR, is essential for the removal of nitrogen oxide from the flue gas of coal-fired power stations and has been widely used. Due to the strong demand for energy and the requirements for environmental protection, a large amount of SCR catalyst waste is produced. The spent SCR catalyst contains high-grade valuable metals, and proper disposal or treatment of the SCR catalyst can protect the environment and realize resource recycling. This review focuses on the two main routes of regeneration and recycling of spent vanadium−titanium SCR catalysts that are currently most widely commercially used and summarizes in detail the technologies of recycling, high-efficiency recycling, and recycling of valuable components of spent vanadium−titanium SCR catalysts. This review also discusses in depth the future development direction of recycling spent vanadium−titanium SCR catalysts. It provides a reference for promoting recycling, which is crucial for resource recovery and green and lowcarbon development.

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“…Water vapor and sulfur dioxide (SO 2 ) are common contaminants in industrial flue gas, and their presence can lead to the formation of acidic compounds that can corrode and clog the catalyst surface, leading to a decline in its activity. Furthermore, the presence of water can interfere with the adsorption and reaction of ammonia (NH 3 ) on the catalyst surface, which is essential for the reduction of NO x . The challenge of using SCR catalysts is their susceptibility to poisoning by water and sulfur compounds, which can significantly reduce their efficiency and lifespan. , Therefore, the development of SCR catalysts from sintering dust with good water and sulfur resistance is critical for the successful implementation of this technology.…”

Section: Introductionmentioning

confidence: 99%

Performance of an SCR Catalyst from Sintering Dust by the Hydrothermal Method and Its Water/Sulfur Resistance

Zhou

et al. 2023

Energy Fuels

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Durability is an issue for selective catalytic reduction (SCR) catalysts due to their susceptibility to sulfur and water poisoning. In this study, Nano-Ce 10 -PSDC HF /ZrO 2 was prepared by the hydrothermal method using sintering dust, and the impact of SO 2 or water vapor on its SCR performance was investigated. The denitrification performance of Nano-Ce 10 -PSDC HF /ZrO 2 was better than that of 0.25-Ce 10 -PSDC HF /ZrO 2 prepared by the impregnation method in the entire temperature interval from 80 to 400 °C. The highest denitrification rate of 93.6% was achieved at 280 °C. Nano-Ce 10 -PSDC HF /ZrO 2 had a smaller particle size and uniform dispersion but also formed a high concentration of Ce 3+ and adsorbed oxygen O α on the surface. Additionally, it showed better resistance to water and sulfur than 0.25-Ce 10 -PSDC HF /ZrO 2 . Even when exposed to 8% H 2 O and 400 ppm SO 2 , the denitrification rate of Nano-Ce 10 -PSDC HF /ZrO 2 remained at 82.1% after 4 h. SO 2 is more toxic to SCR catalysts than H 2 O. The effect of water on catalyst activity is partially reversible. Deactivation of SCR by SO 2 is primarily caused by the formation of ammonium sulfate species, with some contribution from competitive adsorption between SO 2 and NO x . In conclusion, the Nano-Ce 10 -PSDC HF /ZrO 2 catalyst exhibited the best SCR performance, with water and sulfur resistance, and effectively utilized sintering dust, which has potential application value.

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Recent advances in heighten sulfur resistance of SCR catalysts: A review

Cited by 11 publications

References 65 publications

Effect of Ultrasound Irradiation on the Properties and Sulfur Contents of Blended Very Low-Sulfur Fuel Oil (VLSFO)

Effect of Ultrasound Irradiation on the Properties and Sulfur Contents of Blended Very Low-Sulfur Fuel Oil (VLSFO)

Strategy and Technical Progress of Recycling of Spent Vanadium–Titanium-Based Selective Catalytic Reduction Catalysts

Performance of an SCR Catalyst from Sintering Dust by the Hydrothermal Method and Its Water/Sulfur Resistance

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