预测和评估中、低功率锅炉燃烧炉用燃油的碳足迹的可能性

IF 0.7 4区工程技术 Q4 ENGINEERING, CHEMICAL

Theoretical Foundations of Chemical Engineering Pub Date : 2024-01-17 DOI:10.1134/S0040579523050470

T. Z. Maimekov, D. A. Sambaeva, M. B. Moldobaev, T. S. Bazhirov, Z. K. Maimekov

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引用次数: 0

摘要

为了预测和评估气相中的碳足迹，研究了炉燃料油在过量空气（α系数 1.3）中的氧化过程，温度范围很宽（T = 298-3000 K，P = 0.1 MPa）。确定了气相中的平衡热力学参数（熵、焓和内能）以及含 C、S、N、O 和 H 成分和活性颗粒的浓度分布。根据气相中含 C、S、N、O 和 H 成分及活性颗粒的总浓度分布，计算出碳的重量含量。考虑到熔炉燃料油-空气系统的化学基质和碳的重量含量，得出了气相中碳的人为负荷。这项工作的结果使我们有可能评估气相中由于燃料燃烧，特别是炉用燃油在空气中燃烧而产生的碳足迹。通过在 E-1/9M 工业锅炉中改良和燃烧水包油（反向）乳化液形式的炉用燃油，减少了气相中碳氧化物（一氧化碳、二氧化碳）的人为负荷。

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Possibilities for Prediction And Evaluation of the Carbon Footprint in Furnace Fuel Oil Combustion in Medium- and Low-Power Boilers

To predict and evaluate the carbon footprint in the gas phase, furnace fuel oil oxidation in excess air (alpha factor 1.3) was studied over a wide temperature (T = 298–3000 K, P = 0.1 MPa). Equilibrium thermodynamic parameters (entropy, enthalpy, and internal energy) and the concentration distributions of C-, S-, N-, O-, and H-containing components and active particles in the gas phase were determined. Based on the total concentration distribution of C-, S-, N-, O-, and H-containing components and active particles in the gas phase, the weight content of carbon was calculated. Taking into account the chemical matrix of the furnace fuel oil–air system and the weight content of carbon, the man-made load of carbon in the gas phase was found. The results of the work made it possible to evaluate the carbon footprint in the gas phase because of the combustion of fuel, in particular, furnace fuel oil in air. Reduction of the man-made load of carbon oxides (CO, CO₂) in the gas phase was achieved by modifying and burning furnace fuel oil in the form of oil-in-water (reverse) emulsions in E-1/9M industrial boilers.

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来源期刊

Theoretical Foundations of Chemical Engineering 工程技术-工程：化工

CiteScore

1.20

自引率

25.00%

发文量

审稿时长

24 months

期刊介绍： Theoretical Foundations of Chemical Engineering is a comprehensive journal covering all aspects of theoretical and applied research in chemical engineering, including transport phenomena; surface phenomena; processes of mixture separation; theory and methods of chemical reactor design; combined processes and multifunctional reactors; hydromechanic, thermal, diffusion, and chemical processes and apparatus, membrane processes and reactors; biotechnology; dispersed systems; nanotechnologies; process intensification; information modeling and analysis; energy- and resource-saving processes; environmentally clean processes and technologies.