The influence of the physichemical behavior of carbon on the melting and crystallization of gasification slag

IF 2.5 4区化学 Q2 Engineering

Chemical Papers Pub Date : 2025-06-01 DOI:10.1007/s11696-025-04130-4

Rongsheng Xu, Dong Sun, Ze Meng, Mengfang Zhang, Tianxi Rao

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Abstract

Residual carbon is an essential component in coal gasification slag, significantly influencing the gasification process. In this study, the impact of the physicochemical behavior of carbon on the melting and crystallization characteristics of gasification slag (GCS) was investigated. When carbon content increased from 2 to 20%, the softening temperature and hemisphere temperature of GCS rose by nearly 120 °C, and the flow temperature by approximately 170 °C. At high temperatures, carbon reduces Fe₂O₃ of slag to elemental Fe and further forms the refractory mineral Fe₃Si. Fe₃Si and residual carbon constitute the framework structure of the melt, delaying the collapse of aluminosilicate melt and thereby increasing the flow temperature of GCS. The increased carbon content in GCS facilitates the formation of Fe₃Si at high temperatures. During the cooling process, the liquid phase in the melts deposits to form a dense aluminosilicate matrix, while refractory phases (Fe₃Si and residual carbon) precipitate and coalesce into spherical aggregates. During the quenching process, the high viscosity of aluminosilicate inhibits the precipitation of refractory phases. As residual carbon content increases, the refractory skeleton disperses more in the high-viscosity melt, creating a denser structure that reduces mass transfer efficiency and promotes the formation of smaller, more dispersed particles instead of larger spheres during cooling.

Graphic abstract

During the coal gasification process, the physicochemical behavior of carbon significantly influences the transformation of minerals and the melting and crystallization characteristics of inorganic ash and slag. At high temperatures, carbon reduces Fe₂O₃ of slag to elemental Fe and further forms the high-melting-point mineral Fe₃Si. The increased carbon content in GCS facilitates the formation of Fe₃Si at high temperatures, while carbon evolves into a refractory framework within the slag, thereby enhancing the fluidity temperature of the GCS. A significant amount of organic carbon precipitates from the aluminosilicate melt in conjunction with iron-rich substances, forming spherical particles under natural cooling conditions. In contrast, during rapid cooling processes, the limited time available prevents extensive migration of carbon from the melt, leading to its partial dispersion within the dense sintered structure. As the carbon content increases, the viscosity of the melt rises, thereby slowing down the precipitation of spherical particles primarily composed of iron-bearing minerals and carbon.

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碳的物理行为对气化渣熔融结晶的影响

残碳是煤气化渣的重要组成部分，对气化过程有重要影响。在本研究中，研究了碳的物理化学行为对气化渣熔融结晶特性的影响。当碳含量从2%增加到20%时，GCS的软化温度和半球温度升高近120℃，流动温度升高约170℃。在高温下，碳将炉渣中的Fe2O3还原为单质铁，并进一步形成难熔矿物Fe3Si。Fe3Si和残余碳构成了熔体的框架结构，延缓了铝硅酸盐熔体的崩塌，从而提高了GCS的流动温度。GCS中碳含量的增加有利于Fe3Si在高温下的形成。在冷却过程中，熔体中的液相沉积形成致密的铝硅酸盐基体，而耐火相（Fe3Si和残余碳）析出并凝聚成球形聚集体。在淬火过程中，高粘度的硅酸铝抑制了耐火相的析出。随着残余碳含量的增加，耐火材料骨架在高粘度熔体中分散得更多，形成更致密的结构，从而降低了传质效率，并在冷却过程中促进形成更小、更分散的颗粒，而不是更大的球体。在煤的气化过程中，碳的物理化学行为对矿物的转化和无机灰渣的熔融结晶特性有显著影响。在高温下，碳将炉渣中的Fe2O3还原为单质铁，并进一步形成高熔点矿物Fe3Si。GCS中碳含量的增加有利于高温下Fe3Si的形成，而碳在渣内演化成耐火骨架，从而提高了GCS的流动温度。从铝硅酸盐中析出的大量有机碳与富铁物质结合在一起，在自然冷却条件下形成球形颗粒。相反，在快速冷却过程中，有限的可用时间阻止了碳从熔体中大量迁移，导致其部分分散在致密的烧结结构中。随着碳含量的增加，熔体的粘度上升，从而减缓了主要由含铁矿物和碳组成的球形颗粒的析出。

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来源期刊

Chemical Papers Chemical Engineering-General Chemical Engineering

CiteScore

3.30

自引率

4.50%

发文量

590

期刊介绍： Chemical Papers is a peer-reviewed, international journal devoted to basic and applied chemical research. It has a broad scope covering the chemical sciences, but favors interdisciplinary research and studies that bring chemistry together with other disciplines.