Soot temperature and KL factor for biodiesel and diesel spray combustion in a constant volume combustion chamber

Soot temperature and KL factor for biodiesel and diesel spray combustion in a constant volume combustion chamber

► Soot temperature and concentration of spray combustion measured using two color thermometry. ► Uncertainty of the technique was analyzed using statistical methods. ► Biodiesel produces lower soot than diesel. ► Soot temperature decreases with the decrease in ambient temperature. ► Biodiesel soot t...

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Bibliographic Details
Published in:Applied energy Vol. 107; pp. 52 - 65
Main Authors: Zhang, Ji, Jing, Wei, Roberts, William L., Fang, Tiegang
Format: Journal Article
Language:English
Published: Kidlington Elsevier Ltd 01-07-2013
Elsevier
Subjects:
ambient temperature
Applied sciences
Biodiesel
combustion
Constant volume chamber
Diesel
diesel fuel
emissions
Energy
Exact sciences and technology
heat
oxygen
soot
Spray combustion
statistical analysis
Two-color thermometry
uncertainty
Spray combustion
Diesel
Two-color thermometry
Biodiesel
Constant volume chamber
Temperature
Combustion chamber
Diesel fuel
Biofuel
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Summary:► Soot temperature and concentration of spray combustion measured using two color thermometry. ► Uncertainty of the technique was analyzed using statistical methods. ► Biodiesel produces lower soot than diesel. ► Soot temperature decreases with the decrease in ambient temperature. ► Biodiesel soot temperature is lower than diesel for 1000K and 1200K ambient. This paper presents measurements of the soot temperature and KL factor for biodiesel and diesel combustion in a constant volume chamber using a two-color technique. This technique uses a high-speed camera coupled with two narrowband filters (550nm and 650nm, 10nm FWHM). After calibration, statistical analysis shows that the uncertainty of the two-color temperature is less than 5%, while it is about 50% for the KL factor. This technique is then applied to the spray combustion of biodiesel and diesel fuels under an ambient oxygen concentration of 21% and ambient temperatures of 800, 1000 and 1200K. The heat release result shows higher energy utilization efficiency for biodiesel compared to diesel under all conditions; meanwhile, diesel shows a higher pressure increase due to its higher heating value. Biodiesel yields a lower temperature inside the flame area, a longer soot lift-off length, and a smaller soot area compared to diesel. Both the KL factor and the total soot with biodiesel are lower than with diesel throughout the entire combustion process, and this difference becomes larger as the ambient temperature decreases. Biodiesel shows approximately 50–100K lower temperatures than diesel at the quasi-steady stage for 1000 and 1200K ambient temperature, while diesel shows a lower temperature than biodiesel at 800K ambient. This result may raise the question of how important the flame temperature is in explaining the higher NOx emissions often observed during biodiesel combustion. Other factors may also play an important role in controlling NOx emissions. Both biodiesel and diesel temperature measurements show a monotonic dependence on the ambient temperature. However, the ambient temperature appears to have a more significant effect on the soot formation and oxidation in diesel combustion, while biodiesel combustion soot characteristics shows relative insensitivity to the ambient temperature.
Bibliography:http://dx.doi.org/10.1016/j.apenergy.2013.02.023
ObjectType-Article-1
SourceType-Scholarly Journals-1
ObjectType-Feature-2
content type line 23
ISSN:0306-2619
1872-9118
DOI:10.1016/j.apenergy.2013.02.023