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掺混生物重油的煤燃料的燃烧特性及污染物分析

Combustion properties and pollutant analysis of coal-blended bio-heavy oil fuel.

作者信息

Bai Yuan, Sun Yuqing, Pan Haojun, Wang Sheng, Dong Yuehong, Chen Bin, Qiu Jian, Jing Wenheng

机构信息

State Key Laboratory of Low-Carbon Smart Coal-Fired Power Generation and Ultra-Clean Emission, China Energy Science and Technology Research Institute Co., Ltd Nanjing China.

Guodian Environmental Protection Research Institute Co., Ltd Nanjing China.

出版信息

RSC Adv. 2024 Jan 31;14(7):4362-4368. doi: 10.1039/d3ra08748d.

DOI:10.1039/d3ra08748d
PMID:38304568
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10828933/
Abstract

Excessive carbon-dioxide emissions drive global climate change and environmental challenges. Integrating renewable biomass fuels with coal in power units is crucial for achieving low-carbon emission reductions. Coal blending with bio-heavy oil enhances the combustion calorific value of the fuel, improves combustion characteristics, and decreases pollutant emissions. This study found that bio-heavy oil with low sulfur (0.073%), low nitrogen (0.18%), low ash, and high oxygen (11.005%) content exhibits excellent fuel performance, which can be attributed to the abundant oxygen-containing functional groups (such as C[double bond, length as m-dash]O) in the alcohols, aldehydes, and ketones present in bio-heavy oil. Additionally, the residual moisture in coal-blended bio-heavy oil reduces the fuel's calorific value. The calorific value increases with a higher proportion of blended bio-heavy oil (28.1, 28.9, 32.1, 34.7, 40.6 MJ kg). Experiments on combustion flame shooting reveal that the combustion time of bio-heavy oils is significantly shorter than that of coal. As the proportion of blended bio-heavy oil increases, the flame height increases. Coal blending with bio-heavy oil involves three stages: water evaporation, volatile-matter decomposition, fixed-carbon combustion and mineral decomposition. This advances the combustion process and improves coal's ignition performance. Furthermore, the amount of gaseous pollutants (sulfur dioxide and nitrogen dioxide) in coal mixed with bio-heavy oil is relatively low, which is in alignment with the green environmental protection guidelines. The blending of coal with biomass fuel holds significant practical and strategic importance for developing high-efficiency, low-carbon, coal power units.

摘要

过量的二氧化碳排放推动了全球气候变化和环境挑战。在发电单元中将可再生生物质燃料与煤炭整合对于实现低碳减排至关重要。煤炭与生物重油混合可提高燃料的燃烧热值,改善燃烧特性,并减少污染物排放。本研究发现,硫含量低(0.073%)、氮含量低(0.18%)、灰分低且氧含量高(11.005%)的生物重油表现出优异的燃料性能,这可归因于生物重油中存在的醇、醛和酮类中丰富的含氧官能团(如C=O)。此外,掺混生物重油的煤炭中的残余水分会降低燃料的热值。随着掺混生物重油比例的提高,热值增加(28.1、28.9、32.1、34.7、40.6兆焦/千克)。燃烧火焰喷射实验表明,生物重油的燃烧时间明显短于煤炭。随着掺混生物重油比例的增加,火焰高度增加。煤炭与生物重油混合涉及三个阶段:水分蒸发、挥发物分解、固定碳燃烧和矿物质分解。这推进了燃烧过程并改善了煤炭的着火性能。此外,与生物重油混合的煤炭中气态污染物(二氧化硫和二氧化氮)的含量相对较低,这符合绿色环保准则。煤炭与生物质燃料的混合对于开发高效、低碳的燃煤发电单元具有重大的实践和战略意义。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/95a4/10828933/41b66f4f4719/d3ra08748d-f8.jpg
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https://cdn.ncbi.nlm.nih.gov/pmc/blobs/95a4/10828933/41b66f4f4719/d3ra08748d-f8.jpg
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