Preheating and combustion characteristics of high-alkali coal with a novel circulating fluidized bed route

Waste Disposal & Sustainable Energy Pub Date : 2025-05-04 DOI:10.1007/s42768-025-00227-4

Dongxu Zhang, Huizhong Han, Jianguo Zhu

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Abstract

China possesses abundant reserves of high-alkali coal, however, its combustion presents challenges such as slagging and fouling. Achieving efficient and clean combustion of high-alkali coal remains a significant technical challenge. This study utilizes novel circulating fluidized bed (CFB) preheating combustion technology to investigate the effects of varying air equivalence ratios on the preheating, combustion, and NO_x emission characteristics of high-alkali coal in a kW-level hot-state experimental platform. Results indicate that the preheater intensifies the fragmentation of high-alkali coal particles, decreasing the median particle size (d₅₀) from 710.9 μm in high-alkali coal to 17.1 μm in preheated char. At an air equivalence ratio of 0.35, the calorific value of the preheated coal gas reaches a peak of 2.46 MJ/Nm³. Across various air equivalence ratios, the NH₃ concentration in the preheated coal gas consistently exceed those of HCN. With the air equivalence ratio increases, the release rates of C, N, and S from the high-alkali coal also rise, while the CO/CO₂ ratio of the preheated coal gas remains below 1.0. And the S release rate is lower than that of C and N. During the combustion of preheated fuel in the combustion chamber, the temperature distribution remains uniform, with NO_x emissions ranging from 200 to 230 mg/m³. The minimum conversion ratio of coal N to NO_x in this system is 10.8%. This investigation might support the development and application of high-alkali coal combustion technology.

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新型循环流化床高碱煤的预热与燃烧特性

中国拥有丰富的高碱煤储量，但其燃烧存在结渣、结垢等问题。实现高碱煤的高效清洁燃烧仍然是一个重大的技术挑战。本研究利用新型循环流化床（CFB）预热燃烧技术，在kw级热态实验平台上研究了不同空气当量比对高碱煤预热、燃烧和NOx排放特性的影响。结果表明：预热器强化了高碱煤颗粒的破碎，使高碱煤的中位粒径（d50）从710.9 μm减小到17.1 μm；在空气当量比为0.35时，预热煤气的热值达到峰值2.46 MJ/Nm3。在不同的空气当量比下，预热煤气中NH3浓度始终高于HCN浓度。随着空气当量比的增大，高碱煤中C、N、S的释放速率也随之增大，而预热煤气的CO/CO2比保持在1.0以下。S的释放速率低于C和n。预热燃料在燃烧室燃烧时，温度分布保持均匀，NOx排放量在200 ~ 230 mg/m3之间。该系统中煤N与NOx的最小转化率为10.8%。该研究为高碱煤燃烧技术的开发和应用提供了理论依据。图形抽象

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Waste Disposal & Sustainable Energy

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