Influence of Temperature and CO<sub>2</sub> on High-Temperature Behavior and Microstructure of Metallurgical Coke

Wang, Mingyu; Liu, Zhenggen; Chu, Mansheng; Shi, Quan; Tang, Jue; Han, Dongmei; Cao, Laigeng

doi:10.1021/acsomega.1c01675

Cited by 8 publications

(4 citation statements)

References 26 publications

(50 reference statements)

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“…Therefore, the quality of metallurgical coke is closely related to the technical and economic indicators of blast furnaces. Mansheng et al found that from 1100 °C to 1500 °C, the coke weight-loss ratio increased by 10-fold, and the drum strength decreased by 80%; in a CO 2 atmosphere, when the temperature increased from 1100 °C to 1300 °C, the coke reactivity increased by 50%, and the coke strength decreased after the reaction [ 13 ]. Zhongsuo used different methods to analyze the kinetics of carbon dioxide gasification of metallurgical coke, and proposed new kinetic equations and predicted kinetic curves [ 14 ].…”

Section: Introductionmentioning

confidence: 99%

Metallurgical Coke Combustion with Different Reactivity under Nonisothermal Conditions: A Kinetic Study

Qin

Ling

et al. 2022

Materials

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The combustion characteristics and kinetics of high- and low-reactivity metallurgical cokes in an air atmosphere were studied by thermogravimetric instrument. The Coats–Redfern, FWO, and Vyazovkin integral methods were used to analyze the kinetics of the cokes, and the kinetic parameters of high- and low-reactivity metallurgical cokes were compared. The results show that the heating rate affected the comprehensive combustion index and combustion reaction temperature range of the cokes. The ignition temperature, burnout temperature, combustion characteristics, and maximum weight-loss rate of low-reactivity coke (L-Coke) were better than high-reactivity coke (H-Coke). Low-reactivity coke had better thermal stability and combustion characteristics. At the same time, it was calculated via three kinetic analysis methods that the combustion activation energy gradually decreased with the progress of the reaction. The coke combustion activation energy calculated by the Coats–Redfern method was larger than the coke combustion activation energy calculated by the FWO and Vyazovkin methods, but the laws were consistent. The activation energy of L-Coke was about 4~8 kJ/mol more than that of H-Coke.

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Section: Introductionmentioning

confidence: 99%

Metallurgical Coke Combustion with Different Reactivity under Nonisothermal Conditions: A Kinetic Study

Qin

Ling

et al. 2022

Materials

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“…The carbon structure and pore characteristics of metallurgical coke have a significant impact on coke behavior and reactivity in a blast furnace. The basic unit of the carbon structure is a graphite crystallite, and the size of the graphite crystallite can usually be characterized by the stacking height Lc of the carbon substrate. , In this study, the stacking height Lc was calculated using Origin. First, the XRD data was drawn, and then the “multipeak fitting” was carried out.…”

Section: Resultsmentioning

confidence: 99%

Coupled Typical Coke Gasification and Sintering Ore Reduction in CO–N₂–H₂

Qin

et al. 2022

ACS Omega

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Through thermodynamic calculation and high-temperature simulation experiments, the coupling behavior between gasification of high- and low-reactivity cokes and reduction of sintering ore in CO–N 2 –H 2 mixed gas with 25% H 2 volume fraction was studied, and the evolution of the coke carbon structure and the pore structure was analyzed. The results show that the reaction rate of the two cokes increases with the increase in temperature after the coupling reaction, and the strength after drumming decreases with the increase in temperature. The strength of low-reactivity coke after the reaction is higher than that of high-reactivity coke, and the reduction degree of sintering ore after the coupling reaction with low-reactivity coke is higher than that with high-reactivity coke. At high temperatures and high hydrogen-rich atmospheres with φ(H 2 ) of 25%, the strength of high-reactivity coke after drum rotation is greater than 60.4%. The graphitization degree and carbon structure order of low-reactivity coke are higher than those of high-reactivity coke.

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“…Therefore, the microcrystalline structure of coke is an important factor affecting coke reactivity. 24 Figure 2 shows the XRD spectra of coke obtained from coal blends with different proportions of GL. The addition of GL weakens the peak intensities of 002 and 100, which represent the size and orientation of the carbon reticulum layer in the aromatic ring of coke, respectively.…”

Section: Resultsmentioning

confidence: 99%

“…The edge of the coke microcrystal belongs to the defect site of the crystal lattice, which can form unsaturated chemical bonds easily by combining heteroatoms, and becomes the active center during gasification reaction to promote the gasification activity. Therefore, the microcrystalline structure of coke is an important factor affecting coke reactivity Figure shows the XRD spectra of coke obtained from coal blends with different proportions of GL.…”

Section: Resultsmentioning

confidence: 99%

Effects of Additives on Coke Reactivity and Sulfur Transformation during Co-pyrolysis of Long Flame Coal and High-Sulfur Coking Coal

Shen

Guo

et al. 2021

ACS Omega

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A silica-aluminum-based mineral (GL) was selected for inspecting the effects of interactions of minerals in coal blends on the coke reactivity index (CRI) and sulfur transformation during co-pyrolysis of long flame coal and high-sulfur coking coal. Results indicate a good compatibility for the supply of active hydrogen, decomposition of sulfur, and regulation of reactivity. The experimental values of sulfur content in different coal blend cokes are lower than the calculated values, which can be determined as a result of the directional regulation effect of long flame coal on sulfur transformation. The addition of GL in coal blends significantly reduces the CRI of the corresponding coke, and the effect of GL on coke reactivity is also verified by a 10 kg coke oven experiment. When increasing the ratio of long flame coal, the sulfur fixation in the solid phase has a tendency to be enhanced by alkaline minerals. Also, GL plays a role in reducing the capture of sulfur free radicals by alkaline minerals, which improves the sulfur removal during pyrolysis of coal blends and then reduces the sulfur content in coke. This work provides a reference for using silica-aluminum-based minerals to reduce the capture of sulfur and catalytic effect on coke reactivity.

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Influence of Temperature and CO₂ on High-Temperature Behavior and Microstructure of Metallurgical Coke

Cited by 8 publications

References 26 publications

Metallurgical Coke Combustion with Different Reactivity under Nonisothermal Conditions: A Kinetic Study

Metallurgical Coke Combustion with Different Reactivity under Nonisothermal Conditions: A Kinetic Study

Coupled Typical Coke Gasification and Sintering Ore Reduction in CO–N₂–H₂

Effects of Additives on Coke Reactivity and Sulfur Transformation during Co-pyrolysis of Long Flame Coal and High-Sulfur Coking Coal

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Influence of Temperature and CO2 on High-Temperature Behavior and Microstructure of Metallurgical Coke

Cited by 8 publications

References 26 publications

Metallurgical Coke Combustion with Different Reactivity under Nonisothermal Conditions: A Kinetic Study

Metallurgical Coke Combustion with Different Reactivity under Nonisothermal Conditions: A Kinetic Study

Coupled Typical Coke Gasification and Sintering Ore Reduction in CO–N2–H2

Effects of Additives on Coke Reactivity and Sulfur Transformation during Co-pyrolysis of Long Flame Coal and High-Sulfur Coking Coal

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Influence of Temperature and CO₂ on High-Temperature Behavior and Microstructure of Metallurgical Coke

Coupled Typical Coke Gasification and Sintering Ore Reduction in CO–N₂–H₂