Promoting Silicate Formation by Alkali Chloride Solid Solution during Thermal Conversion of Silicon-Containing Solid Fuels

Cheng, Mingkai; Chen, Sheng; Zhu, Hongwei; Zhao, Xuan; Bai, Jin

doi:10.1021/acs.energyfuels.4c00140

Energy Fuels

2024

DOI: 10.1021/acs.energyfuels.4c00140

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Promoting Silicate Formation by Alkali Chloride Solid Solution during Thermal Conversion of Silicon-Containing Solid Fuels

Mingkai Cheng,

Sheng Chen,

Hongwei Zhu

et al.

Abstract: The development of solid fuel combustion power generation technology in China has been significantly hindered by alkali-related issues including fouling, slagging, and particulate matter emission. Consequently, understanding the formation of silicates in the alkali–silica reaction (ASR) becomes crucial for addressing alkali-related issues associated with solid fuels. However, the complex composition of these fuels and the unknown interaction between multiple alkali chlorides (NaCl and KCl) hinder a comprehensi… Show more

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Cited by 2 publications

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Interaction Between Alkali Chlorides and Ilmenite in Chemical Looping Combustion

Dubey,

Mei,

Lyngfelt

et al. 2024

Energy Fuels

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Chemical looping combustion (CLC) is an emerging combustion technology recognized for its high efficiency and minimal environmental impact in terms of CO 2 emissions. When biomass is used in CLC, the process referred to as Bio-CLC, it can result in negative CO 2 emissions. However, the presence of alkalis (K and Na) in biomass can pose operational challenges. To better understand how alkalis interact with oxygen carriers, this study utilized a method involving the impregnation of charcoal particles with alkali salts (KCl or NaCl or both). The influence of alkali chlorides on fluidization/agglomeration, reactivity, and interaction with ilmenite was investigated in a batch fluidized bed reactor operating at 950 °C. During the reduction step of the simulated CLC cycles with solid fuels, charcoal impregnated with KCl (K-charcoal), NaCl (Na-charcoal), and a combination of both (Na−K charcoal) was used. A total of 33 alkali cycles were performed with K-charcoal, Na-charcoal, and Na−K charcoal with calcined ilmenite, as well as Na−K charcoal with synthetic ilmenite, including additional cycles using nonimpregnated charcoal as a reference. Na−K charcoal with calcined ilmenite led to an earlier onset of agglomeration and defluidization than single-impregnated charcoal. In contrast, no defluidization was observed in the case of synthetic ilmenite with Na−K charcoal. EDX analyses revealed minimal Na and no K accumulation in the particle bridges of the final Na-ilmenite and K-ilmenite samples. Conversely, Na and K were found together with Si and Al in the particle bridges of the final Na−K ilmenite, while no accumulation of Na and K was observed in the final Na−K synthetic ilmenite. ICP-OES analyses showed that approximately 28% of K and 49% of Na were retained in the final Kilmenite and Na-ilmenite, respectively. Negative K retention and 40% Na were observed in the final Na−K ilmenite, whereas 35% K and 40% Na retention were found in the final Na−K synthetic ilmenite. This research significantly enhances our understanding of the interactions between alkali chlorides and ilmenite.

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Interaction Between Alkali Chlorides and Ilmenite in Chemical Looping Combustion

Dubey,

Mei,

Lyngfelt

et al. 2024

Energy Fuels

View full text Add to dashboard Cite

show abstract

Ca- and Ba-Decorated CuO Oxygen Carriers for In Situ Dechlorination in Chemical Looping Combustion

Ma,

Mi,

Wang

et al. 2024

Energy Fuels

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In the chemical looping combustion of chlorine-rich biomass or coal, a trace element, chlorine, will cause serious corrosion of oxygen carriers and heat exchange equipment in boilers. To address this issue, we design Ca-and Ba-decorated oxygen carriers to achieve two goals: on one hand, reducing the concentration of chlorine-containing gases by in situ dechlorination; on the other hand, employing protective materials to preferentially bind with gaseous chlorine to safeguard the active components of the oxygen carriers. Carefully designed experiments are conducted under simplified experimental conditions using 50 ppmv HCl-containing CH 4 to evaluate the intrinsic characteristics of oxygen carriers in terms of dechlorination efficiency and reactivity. The results demonstrate that both the reaction performance and the chlorine-resistance performance of Ca−Cu and Ba−Cu composite oxygen carriers are significantly improved. This is because (a) Ca and Ba preferentially form chlorides with HCl, effectively shielding the active Cu component of the oxygen carrier from chlorine poisoning and (b) the specific surface area and pores of Ca/Ba-decorated oxygen carriers are increased, which not only strengthens the heterogeneous reaction between oxygen carrier and combustible gas but also improves the chemical looping combustion performance. The Cl-resistant oxygen carriers, Ca−Cu and Ba−Cu, emerge as promising candidates for the chemical looping combustion of fuels with high chlorine content.

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Promoting Silicate Formation by Alkali Chloride Solid Solution during Thermal Conversion of Silicon-Containing Solid Fuels

Cited by 2 publications

References 52 publications

Interaction Between Alkali Chlorides and Ilmenite in Chemical Looping Combustion

Interaction Between Alkali Chlorides and Ilmenite in Chemical Looping Combustion

Ca- and Ba-Decorated CuO Oxygen Carriers for In Situ Dechlorination in Chemical Looping Combustion

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