烷烃燃料微小平板催化燃烧的火焰特性

姚彦伊; 王业峰; 杨卫娟; 赵庆辰; 周俊虎; 程军

doi:10.3969/j.issn.2095-560X.2018.05.003

新能源进展 >

2018 , Vol. 6 >Issue 5: 353 - 358

DOI: https://doi.org/10.3969/j.issn.2095-560X.2018.05.003

研究论文

烷烃燃料微小平板催化燃烧的火焰特性

姚彦伊 ,
王业峰 ,
杨卫娟 ,
赵庆辰 ,
周俊虎 ,
程军

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浙江大学热能工程研究所,杭州 310027

姚彦伊（1993-）,女,博士研究生,主要从事烷类燃料及合成气催化燃烧实验及数值模拟研究。杨卫娟（1976-）,女,博士,教授,主要从事能源与环境领域的基础及技术研究。

收稿日期: 2018-01-05

修回日期: 2018-05-28

网络出版日期: 2018-10-31

基金资助

国家自然科学基金项目（51336010）; 中央高校基本科研业务费专项资金项目（2016FZA4011）

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Flame Characteristics of Catalytic Combustion of Alkane Fuels in Micro-Flat Combustor

YAO Yan-yi ,
WANG Ye-feng ,
YANG Wei-juan ,
ZHAO Qing-chen ,
ZHOU Jun-hu ,
CHENG Jun

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Institute for Thermal Power Engineering, Zhejiang University, Hangzhou 310027, China

Received date: 2018-01-05

Revised date: 2018-05-28

Online published: 2018-10-31

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摘要

对微平板燃烧器内4种烷类燃料（C₁ ~ C₄）进行铂催化燃烧实验,获得其点火过程和静态火焰的特征,并进行对比分析。当量比相同时,点火过程火焰传播速度大小顺序为甲烷 > 乙烷 > 丁烷 > 丙烷。随着当量比增大,火焰传播速度加快,稳态火焰根部位置向气流上游移动。观察可见光、430 nm（OH*光谱）、516 nm（C₂*光谱）成像火焰发现,当量比越大,火焰亮度越大,OH*和C₂*浓度越高。当量比相同时,乙烷的OH*、CH*和C₂*浓度最高,而甲烷和丙烷的则较低。

关键词： 甲烷; 乙烷; 丙烷; 正丁烷; 催化剂; 微尺度燃烧

本文引用格式

姚彦伊 , 王业峰 , 杨卫娟 , 赵庆辰 , 周俊虎 , 程军 . 烷烃燃料微小平板催化燃烧的火焰特性[J]. 新能源进展, 2018 , 6(5) : 353 -358 . DOI: 10.3969/j.issn.2095-560X.2018.05.003

Abstract

Combustion of four alkane fuels (C₁ ~ C₄) in a micro-plat combustor catalyzed by Platinum were performed to studied their ignition process and static flame. When with a same equivalent ratio, the order of the flame propagation velocity was methane > ethane > butane > propane. The propagation velocity increase with the equivalent ratio, and the steady-state flame root position of the fuels move upstream of the airflow. Flame images of the visible light, 430 nm (OH* spectrum), 516 nm (C₂* spectrum) were observed, and it was found that, the larger the equivalent ratio was the greater the flame intensity was in the same fuel, and the concentration of OH* and C₂* were higher. Under the same equivalent ratio condition, the OH*, CH*, and C₂* concentrations of ethane were the highest, while the concentrations of methane and propane were lower.

Key words： methane; ethane; propane; n-butane; catalyst; micro-scale combustion

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