Exploiting the Molten Slag to Decarbonize Iron and Steel Industry: Feasibility Analysis of Centrifugal Granulation‐Assisted Thermal Energy Recovery System beyond Pilot Scale

Wu, Jian; Wang, Hong; Zhu, Xun; Liu, Qiang

doi:10.1002/srin.202200300

Cited by 6 publications

(2 citation statements)

References 35 publications

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“…The ultimate outcome of this process is the generation of N 2 and H 2 O, effectively achieving the removal of NO x . [12][13][14] This technology offers high denitration efficiency and avoids secondary pollution, making it extensively used in industrial denitration. [15][16][17] The catalyst is the core component of denitration technology.…”

Section: Introductionmentioning

confidence: 99%

Preparation and Application of Slag‐Based Catalyst for Steelmaking

Zhang,

Wang,

Song

et al. 2024

steel research int.

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This study focuses on utilizing ground granulated blast furnace slag (GGBS) from a steel plant as the main raw material, with water and calcium‐based montmorillonite as binders, with manganese and alkali metal nitrates (Na, K, Mg, Ca). A series of supported denitration catalysts are prepared using the equal volume impregnation method. These catalysts are then employed in the selective catalytic reduction process to investigate their impact on denitration effectiveness. Furthermore, the mechanism of low‐temperature denitration in selective catalytic reduction is analyzed by combining catalyst activity tests and characterization techniques. The activity of catalysts is assessed through Fourier transform infrared spectrometer (FT‐IR), X‐Ray diffraction (XRD), and search engine marketing (SEM) characterization tests, along with examining its denitration and sulfur resistance capabilities to determine the denitration mechanism. Experimental results indicate that Mn–Mg/GGBS exhibit the most efficient low‐temperature denitrification effect, and it demonstrates certain sulfur resistance with a 5% Mn loading and a 3% second active component. Introducing Ce as the third active component further enhances the sulfur resistance of Mn–Mg–Ce/GGBS when loaded at 1%.

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Section: Introductionmentioning

confidence: 99%

Preparation and Application of Slag‐Based Catalyst for Steelmaking

Zhang,

Wang,

Song

et al. 2024

steel research int.

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“…The working principles and status of the aforementioned DSG examples have been well reviewed by Barati et al [8] and Zhang et al [1] Notably, centrifugalgranulation-assisted thermal energy recovery (CGATER) is gaining the spotlight for its potential to recover the heat from BF slag without hampering the hydrate activity of BF slag. [9][10][11] The CGATER has been intensively tested at laboratory [9] and more recently, important CGATER trials were carried out at pilot scales in Australia, [12,13] Europe, [14] and China. These preeminent efforts make the CGTAER stand out from the available DSG methods; it is regarded as the leading technology for low-carbon slag treatment in the iron making industry.…”

Section: Introductionmentioning

confidence: 99%

High‐Temperature Thermophysical Property Characterization of Molten Blast Furnace Slag: A Critical Reviews

Liu

et al. 2023

steel research int.

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Centrifugal granulation‐assisted thermal energy recovery (CGATER) remains the leading technology for the iron and steel industry to enable the low‐carbon treatment of high‐temperature blast furnace (BF) slag. Accurate knowledge of the thermophysical properties of BF slag is pivotal for the commercialization of the CGATER. However, it presents a formidable task to obtain these quantities due to the extremely high temperature of molten BF slag (≈1500 °C). To date, the thermophysical properties of BF slag have not been well characterized yet. Herein, five typical thermophysical properties including density, viscosity, surface tension, thermal conductivity, and emissivity are scrutinized with emphasis on the experimental measurements and empirical estimates. The working principles of these measurement methods are briefly overviewed and their merits and demerits are highlighted. It is noted that density, viscosity, and surface tension have been intensively studied; the quantities can be estimated with moderate uncertainty. However, the thermal conductivity and emissivity of BF slag are less tackled, mainly because of the scarcity of measurement tools at high temperatures. In the future, innovative measurement tools tailored for high‐temperature materials are essential, not only for enriching the thermophysical property database of BF slag but also for paving the way toward characterizing other complex high‐temperature melts.

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Film flow of molten slag on rotary cup: Transient heat transfer, steady state projection and thermal insulation

Lv,

Dai,

et al. 2025

Applied Thermal Engineering

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Exploiting the Molten Slag to Decarbonize Iron and Steel Industry: Feasibility Analysis of Centrifugal Granulation‐Assisted Thermal Energy Recovery System beyond Pilot Scale

Cited by 6 publications

References 35 publications

Preparation and Application of Slag‐Based Catalyst for Steelmaking

Preparation and Application of Slag‐Based Catalyst for Steelmaking

High‐Temperature Thermophysical Property Characterization of Molten Blast Furnace Slag: A Critical Reviews

Film flow of molten slag on rotary cup: Transient heat transfer, steady state projection and thermal insulation

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