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Journal of Thermal Science

热科学学报

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2025 , Vol. 34 >Issue 3: 720 - 737

DOI: https://doi.org/10.1007/s11630-025-2071-z

Physicochemical Properties and Combustion Performance of Coal Gasification Fine Slag Obtained from Different Entrained-Flow Gasifiers

  • ZHANG Xuefei ,
  • YANG Zhao ,
  • ZHU Zhiping
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  • 1. State Key Laboratory of Coal Conversion, Institute of Engineering Thermophysics, Chinese Academy of Sciences, Beijing 100190, China
    2. University of Chinese Academy of Sciences, Beijing 100049, China
    3. Shanxi Engineering Research Center of Coal Clean, Efficient Combustion and Gasification, Datong 037000, China
    4. Shanxi Key Laboratory of Coal Flexible Combustion and Thermal Conversion, Datong 037000, China

Online published: 2025-05-06

Supported by

This work was financially supported by the Strategic Priority Research Program of the Chinese Academy of Sciences (No. XDA29020300).

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Science Press, Institute of Engineering Thermophysics, CAS and Springer-Verlag GmbH Germany, part of Springer Nature 2025
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Abstract

The inferior flammability of coal gasification fine slag (CGFS) from entrained-flow gasifiers hampers its resourceful utilization. However, the reasons behind its poor flammability still need to be investigated. This paper conducted a comparative study on the combustion characteristics of three CGFS samples: CGFSGSP, CGFSSN, and CGFSOMB (subscripts GSP, SN, and OMB representing different gasification processes), using experimental techniques such as TG/DTG and combustion kinetic model fitting methods. Additionally, a comprehensive investigation into the physicochemical properties of CGFS was conducted. The objective was to elucidate the causes behind the poor flammability of CGFS. The results revealed that CGFS exhibits lower volatile matter content and higher activation energy than their corresponding raw coal (RC), leading to a significantly higher ignition temperature. The ignition temperatures of RC1, RC2, and RC3 are 361.82°C, 378.66°C, and 404.99°C, respectively. In contrast, the ignition temperatures of CGFSGSP, CGFSSN, and CGFSOMB are 549.08°C, 566.58°C, and 532.67°C, respectively. During the combustion reaction, the temperature (Tmax) at which CGFS reaches its maximum weight loss rate is significantly higher than the temperature (TmaxIII) at which fixed carbon in raw coal reaches its maximum weight loss rate. The TmaxIII of RC1, RC2, and RC3 are 450.90°C, 457.19°C, and 452.77°C, respectively. In contrast, the Tmax of CGFSGSP, CGFSSN, and CGFSOMB are 583.55°C, 608.20°C, and 582.18°C, respectively. The maximum weight loss rate of different types of CGFS is also significantly lower than the fixed carbon combustion maximum weight loss rate of their respective raw coal samples. The physicochemical characterization results of CGFS demonstrate that, compared to the corresponding raw coal, there is a significant reduction in the proportion of active sites in CGFS. Simultaneously, the proportion of C-C/C-H on the surface of residual carbon in CGFS decreases. In contrast, the proportion of O=C-O significantly increases, suggesting a shift toward a more stable state of carbon-containing functional groups. This study is expected to offer essential theoretical support for the efficient combustion utilization of CGFS.

Key words: coal gasification fine slag; combustion characteristics; carbon structure; carbon-containing functional groups

Cite this article

ZHANG Xuefei , YANG Zhao , ZHU Zhiping . Physicochemical Properties and Combustion Performance of Coal Gasification Fine Slag Obtained from Different Entrained-Flow Gasifiers[J]. Journal of Thermal Science, 2025 , 34(3) : 720 -737 . DOI: 10.1007/s11630-025-2071-z

References

[1] Yang Q.Y., Qi X.B., Lyu Q., et al., Physicochemical properties of coal gasification fly ash from circulating fluidized bed gasifier. Journal of Thermal Science, 2023, 32(4): 1710–1720.
[2] Guo X., Tang Y.G., Wang Y.F., et al., Potential utilization of coal gasification residues from entrained-flow gasification plants based on rare earth geochemical characteristics. Journal of Cleaner Production, 2021, 280: 124329.
[3] Guo Y., Zhang Y., Zhao X., et al., Multifaceted evaluation of distribution, occurrence, and leaching features of typical heavy metals in different-sized coal gasification fine slag from Ningdong region, China: A case study. Science of the Total Environment, 2022, 831: 154726.
[4] Pio D.T., Tarelho L.A.C., Industrial gasification systems (>3 MWth) for bioenergy in Europe: Current status and future perspectives. Renewable and Sustainable Energy Reviews, 2021, 145: 111108.
[5] Guo Q.H., Zhou Z.J., Wang F.C., et al., Slag properties of blending coal in an industrial OMB coal water slurry entrained-flow gasifier. Energy Conversion and Management, 2014, 86: 683–688.
[6] Fang N., Li Z.Q., Xie C., et al., Influence of the multi-burner bias angle on the air/particle flow characteristics in an improved fly ash entrained-flow gasifier. Energy, 2021, 234: 121174.
[7] Zhang J.Y., Zuo J., Yuan W.H., et al., Synthesis and characterization of silver nanoparticle-decorated coal gasification fine slag porous microbeads and their application in antistatic polypropylene composites. Powder Technology, 2022, 410: 117891.
[8] Shi D., Zhang J.B., Hou X.J., et al., Adsorption mechanism of a new combined collector (PS-1) on unburned carbon in gasification slag. Science of the Total Environment, 2022, 818: 151856.
[9] Qu J., Zhang J., Li H., et al., A high value utilization process for coal gasification slag: Preparation of high modulus sodium silicate by mechano-chemical synergistic activation. Science of the Total Environment, 2021, 801: 149761.
[10] Wang J., Kong L.X., Bai J., et al., Characterization of slag from anthracite gasification in moving bed slagging gasifier. Fuel, 2021, 292: 120390.
[11] Ren L., Ding L., Guo Q.H., et al., Characterization, carbon-ash separation and resource utilization of coal gasification fine slag: A comprehensive review. Journal of Cleaner Production, 2023, 398: 136554.
[12] Li J.W., Fan S.B., Zhang X.Y., et al., Physicochemical structure, combustion characteristics and SiO2 properties of entrained flow gasification ash. Energy, 2022, 251: 123930.
[13] Dai G., Zheng S., Wang X., et al., Combustibility analysis of high-carbon fine slags from an entrained flow gasifier. Journal of Environmental Management, 2020, 271: 111009.
[14] Chen Z.C., Li J.W., Guan S., et al., Kinetics, thermodynamics and gas evolution of atmospheric circulating fluidized bed coal gasification fly ash combustion in air atmosphere. Fuel, 2021, 290: 119810.
[15] Chen Z.C., Li J.W., Zhang X.Y., et al., Investigation on thermal conversion, kinetics and thermodynamics of coal gasification filter cake ash in oxygen fuel combustion. Fuel, 2022, 330: 125556.
[16] Li J.W., Chen Z.C., Zhang X.Y., et al., Thermal conversion, kinetics, thermodynamics and empirical optimization of combustion performance of coal gasification fine ash in oxygen-enriched atmosphere. Fuel, 2023, 331: 125882.
[17] Guo Y., Guo F.H., Zhou L., et al., Investigation on co-combustion of coal gasification fine slag residual carbon and sawdust char blends: Physiochemical properties, combustion characteristic and kinetic behavior. Fuel, 2021, 292: 120387.
[18] Jia W., Li Y., Li H.C., et al., Synergistic co-combustion of carbon-rich fraction from coal gasification fine slag and corncob char: Performance, mechanism, kinetics, and thermodynamics. Journal of the Energy Institute, 2024, 112: 101481.
[19] Wang W., Li W., Liang C., et al., Decarburization and ash characteristics during melting combustion of fine ash from entrained-flow gasifier. Energy, 2023, 263: 125676.
[20] Jiang D.H., Song W.J., Wang X.F., et al., Physicochemical properties of bottom ash obtained from an industrial CFB gasifier. Journal of the Energy Institute, 2021, 95: 1–7.
[21] Jia W.K., Guo Y., Guo F.H., et al., Co-combustion of carbon-rich fraction from coal gasification fine slag and biochar: Gas emission, ash sintering, heavy metals evolutions and environmental risk evaluation. Chemical Engineering Journal, 2023, 471: 144312.
[22] Guo F.H., Chen L.Q., Li Y., et al., Review on the attribute cognition and carbon-ash-water separation of coal gasification fine slag. Separation and Purification Technology, 2023, 320: 124121.
[23] Chen Z., Tian X., Li J., et al., Physicochemical properties and combustion characteristics of coal gasification fine ash modified by NaOH-HCl hydrothermal treatment. Fuel, 2023, 333: 126592.
[24] Wang W., Li W., Ren Q., et al., Experimental study on thermal modification characteristics of entrained-flow gasified fine ash using circulating fluidized bed. Energy, 2024, 293: 130714.
[25] Guo Y., Ma C.F., Zhang Y.X., et al., Comparative study on the structure characteristics, combustion reactivity, and potential environmental impacts of coal gasification fine slag with different particle size fractions. Fuel, 2022, 311: 122493.
[26] Niu Y., Xu J., Miao Z., et al., Distribution modes of residual carbon and ash in coal gasification fine slag and its feasibility analysis as particle electrodes. Chemosphere, 2022, 303(Pt 3): 135159.
[27] Wang Z., Hong C., Xing Y., et al., Thermal characteristics and product formation mechanism during pyrolysis of penicillin fermentation residue. Bioresource Technology, 2019, 277: 46–54.
[28] Vyazovkin S., Burnham A.K., Criado J.M., et al., ICTAC Kinetics Committee recommendations for performing kinetic computations on thermal analysis data. Thermochimica Acta, 2011, 520(1–2): 1–19.
[29] Wu M.K., The roughness of aerosol particles: Surface fractal dimension measured using nitrogen adsorption. Aerosol Science and Technology, 1996, 25(4): 392–398.
[30] Tang P., Chew N.Y.K., Chan H.-K., et al., Limitation of determination of surface fractal dimension using N2 adsorption isotherms and modified Frenkel-Halsey-Hill theory. Langmuir, 2003, 19(7): 2632–2638.
[31] Zhu S.J., Xu L., Yang L., et al., Effect of physicochemical properties of coal gasification fine ash on its wettability. Advanced Powder Technology, 2021, 32(7): 2123–2136.
[32] Pode R., Potential applications of rice husk ash waste from rice husk biomass power plant. Renewable and Sustainable Energy Reviews, 2016, 53: 1468–1485.
[33] Zhou L., Ren Q.Q., Liang C., et al., Study on the capacity of high-temperature melting technology to treat coal gasification fine slag and characterization of slag obtained. Energy, 2023, 272: 127190.
[34] Shu R., Qiao Q., Guo F., et al., Controlled design of Na-P1 zeolite/ porous carbon composites from coal gasification fine slag for high-performance adsorbent. Environmental Research, 2023, 217: 114912.
[35] Wang Y., Zhang Z., Li L., et al., A novel process to recycle coal gasification fine slag by preparing Si-Fe-Al-Ca alloy. Journal of Environmental Management, 2023, 337: 117681.
[36] Yao X.W., Zhou H.D., Xu K.L., et al., Investigation on the fusion characterization and melting kinetics of ashes from co-firing of anthracite and pine sawdust. Renewable Energy, 2020, 145: 835–846.
[37] Wang J., Yuan Z.S., Kong L.X., et al., The critical condition and kinetics of interaction between residual char and slag in the coal slagging gasifier. Fuel, 2023, 341: 127644.
[38] Yao X.W., Zhou H.D., Xu K.L., et al., Systematic study on ash transformation behaviour and thermal kinetic characteristics during co-firing of biomass with high ratios of bituminous coal. Renewable Energy, 2020, 147: 1453–1468.
[39] Zhang X.Y., Zhu S.J., Zhu J.G., et al., TG-MS study on co-combustion characteristics and coupling mechanism of coal gasification fly ash and coal gangue by ECSA®. Fuel, 2022, 314: 123086.
[40] Chen J., Wang Y., Lang X., et al., Comparative evaluation of thermal oxidative decomposition for oil-plant residues via thermogravimetric analysis: Thermal conversion characteristics, kinetics, and thermodynamics. Bioresource Technology, 2017, 243: 37–46.
[41] Huang Z., Deng Z.B., Chen D.Z., et al., Thermodynamic analysis and kinetic investigations on biomass char chemical looping gasification using Fe-Ni bimetallic oxygen carrier. Energy, 2017, 141: 1836–1844.
[42] Li J.W., Chen Z.C., Zhang X.Y., et al., Structure and reactivity of residual carbon from circulating fluidized bed coal gasification fine ash. Journal of Environmental Chemical Engineering, 2022, 10(3): 107759.
[43] Li J.W., Chen Z.C., Li L.K., et al., Study on pore and chemical structure characteristics of atmospheric circulating fluidized bed coal gasification fly ash. Journal of Cleaner Production, 2021, 308: 127395.
[44] Guo F.H., Zhao X., Guo Y., et al., Fractal analysis and pore structure of gasification fine slag and its flotation residual carbon. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2020, 585: 124148.
[45] Wang H., Liu S.L., Li X.T., et al., Morphological and structural evolution of bituminous coal slime particles during the process of combustion. Fuel, 2018, 218: 49–58.
[46] Shen Y., Lu G.H., Bai Y.H., et al., Structural features of residue carbon formed by gasification of different coal macerals. Fuel, 2022, 320: 123918.
[47] Wei J.T., Guo Q.H., Song X.D., et al., Effect of hydrothermal carbonization temperature on reactivity and synergy of co-gasification of biomass hydrochar and coal. Applied Thermal Engineering, 2021, 183: 116232.
[48] Sadezky A., Muckenhuber H., Grothe H., et al., Raman microspectroscopy of soot and related carbonaceous materials: Spectral analysis and structural information. Carbon, 2005, 43(8): 1731–1742.
[49] Cuesta A., Dhamelincourt P., Laureyns J., et al., Raman microprobe studies on carbon materials. Carbon, 1994, 32(8): 1523–1532.
[50] Ding H., Ouyang Z., Shi Y., et al., Effects of the T-abrupt exit configuration of riser on fuel properties, combustion characteristics and NO emissions with coal self-preheating technology. Fuel, 2023, 337: 126860.
[51] Wang Q., Liu Q., Wang Z.C., et al., Characterization of organic nitrogen and sulfur in the oil shale kerogens. Fuel Processing Technology, 2017, 160: 170–177.
[52] Liu Y., Liu J., Lyu Q., et al., Microstructure analysis of fluidized preheating pulverized coal under O2/CO2 atmospheres. Fuel, 2021, 292: 120386.
[53] Xu S.N., Uzoejinwa B.B., Wang S., et al., Study on co-pyrolysis synergistic mechanism of seaweed and rice husk by investigation of the characteristics of char/coke. Renewable Energy, 2019, 132: 527–542.
[54] Zhang W.D., Sun S.Z., Zhao Y.J., et al., Effects of total pressure and CO2 partial pressure on the physicochemical properties and reactivity of pressurized coal char produced at rapid heating rate. Energy, 2020, 208: 118297.
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