Solid-to-gas phase transition kinetics of diverse potassium occurrence forms during biomass pellet combustion: Time-resolved detection and multi-step modeling

IF 5.8 2区工程技术 Q2 ENERGY & FUELS

Combustion and Flame Pub Date : 2024-10-24 DOI:10.1016/j.combustflame.2024.113750

Sun Cen , Wei Xiaolin , Liu Huimin , Li Sen , Li Fei , Li Teng

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引用次数: 0

Abstract

The solid-to-gas phase transition of potassium during biomass combustion significantly impacts ash-related issues in bioenergy systems, affecting operational efficiency and equipment longevity. However, the specific mechanisms and kinetics of this transition process remain inadequately understood. This work investigates the time-resolved transition of solid-phase potassium to the gas phase during the combustion of rice husk and wheat straw pellets, combining experimental measurements with theoretical modeling. Tunable diode laser absorption spectroscopy (TDLAS) was employed to measure atomic potassium concentrations 15 mm above burning pellets tray, where gas-phase equilibrium is approached. Key combustion characteristics including thermogravimetric profiles, spectral radiation, and temperature were simultaneously monitored. A novel multi-step model was developed to describe the transition of different forms of solid-phase potassium (organic, exchangeable, and inorganic) to the gas phase. This model integrates TDLAS measurements, observed combustion characteristics, and biomass physicochemical properties. Thermodynamic equilibrium calculations were used to estimate the atomic potassium fraction from total gaseous potassium. The results showed that the solid-to-gas phase transition of organic potassium synchronizes with volatiles release. In contrast, the maximum emission rates of inorganic and exchangeable potassium occurred at the onset of char combustion. The developed model agrees well with the online detection experiments and were further validated by offline ICP analysis of residual ash. While not directly simulating gas-solid interface reactions near the particle surface, this work lays groundwork for future multi-scale modeling of particle-laden flows and reactor-scale phenomena in biomass combustion systems.

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生物质颗粒燃烧过程中各种钾发生形式的固相-气相转变动力学：时间分辨检测和多步骤建模

生物质燃烧过程中钾的固相到气相的转变极大地影响了生物能源系统中与灰有关的问题，影响了运行效率和设备寿命。然而，人们对这一转变过程的具体机制和动力学仍缺乏足够的了解。本研究结合实验测量和理论建模，对稻壳和小麦秸秆颗粒燃烧过程中固相钾向气相转化的时间分辨进行了研究。采用可调谐二极管激光吸收光谱（TDLAS）测量燃烧颗粒托盘上方 15 毫米处的原子钾浓度，该处接近气相平衡。同时还监测了热重曲线、光谱辐射和温度等关键燃烧特征。开发了一种新颖的多步骤模型来描述不同形式的固相钾（有机钾、可交换钾和无机钾）向气相的过渡。该模型综合了 TDLAS 测量结果、观察到的燃烧特征和生物质理化特性。热力学平衡计算用于估算气态钾总量中的原子钾部分。结果表明，有机钾从固态到气态的相变与挥发物的释放同步。相反，无机钾和可交换钾的最大排放率发生在炭燃烧开始时。所建立的模型与在线检测实验非常吻合，并通过对残灰的离线 ICP 分析得到了进一步验证。这项工作虽然没有直接模拟颗粒表面附近的气固界面反应，但为今后对生物质燃烧系统中的颗粒载流和反应器尺度现象进行多尺度建模奠定了基础。

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来源期刊

Combustion and Flame 工程技术-工程：化工

CiteScore

9.50

自引率

20.50%

发文量

631

审稿时长

3.8 months

期刊介绍： The mission of the journal is to publish high quality work from experimental, theoretical, and computational investigations on the fundamentals of combustion phenomena and closely allied matters. While submissions in all pertinent areas are welcomed, past and recent focus of the journal has been on: Development and validation of reaction kinetics, reduction of reaction mechanisms and modeling of combustion systems, including: Conventional, alternative and surrogate fuels; Pollutants; Particulate and aerosol formation and abatement; Heterogeneous processes. Experimental, theoretical, and computational studies of laminar and turbulent combustion phenomena, including: Premixed and non-premixed flames; Ignition and extinction phenomena; Flame propagation; Flame structure; Instabilities and swirl; Flame spread; Multi-phase reactants. Advances in diagnostic and computational methods in combustion, including: Measurement and simulation of scalar and vector properties; Novel techniques; State-of-the art applications. Fundamental investigations of combustion technologies and systems, including: Internal combustion engines; Gas turbines; Small- and large-scale stationary combustion and power generation; Catalytic combustion; Combustion synthesis; Combustion under extreme conditions; New concepts.