Abstract The impacts of biodiesel on gaseous and particulate matter (PM) emissions of a JP-8–fueled T63 engine were investigated. Jet fuel was blended with the soybean oil-derived methyl ester biofuel at various concentrations and combusted in the turbine engine. The engine was operated at three power settings, namely ground idle, cruise, and takeoff power, to study the impact of the biodiesel at significantly different pressure and temperature conditions. Particulate emissions were characterized by measuring the particle number density (PND; particulate concentration), the particle size distribution, and the total particulate mass. PM samples were collected for off-line analysis to obtain information about the effect of the biodiesel on the polycyclic aromatic hydrocarbon (PAH) content. In addition, temperature-programmed oxidation was performed on the collected soot samples to obtain information about the carbonaceous content (elemental or organic). Major and minor gaseous emissions were quantified using a total hydrocarbon analyzer, an oxygen analyzer, and a Fourier Transform IR analyzer. Test results showed the potential of biodiesel to reduce soot emissions in the jet-fueled turbine engine without negatively impacting the engine performance. These reductions, however, were observed only at the higher power settings with relatively high concentrations of biodiesel. Specifically, reductions of ∼15% in the PND were observed at cruise and takeoff conditions with 20% biodiesel in the jet fuel. At the idle condition, slight increases in PND were observed; however, evidence shows this increase to be the result of condensed uncombusted biodiesel. Most of the gaseous emissions were unaffected under all of the conditions. The biodiesel was observed to have minimal effect on the formation of polycyclic aromatic hydrocarbons during this study. In addition to the combustion results, discussion of the physical and chemical characteristics of the blended fuels obtained using standard American Society for Testing and Materials (ASTM) fuel specifications methods are presented.
[1]
S. Esterby.
American Society for Testing and Materials
,
2006
.
[2]
Edwin Corporan,et al.
Evaluation of soot particulate mitigation additives in a T63 engine
,
2004
.
[3]
Edwin Corporan,et al.
Influence of Fuel Chemical Composition on Particulate Matter Emissions of a Turbine Engine
,
2004
.
[4]
Howard T. Mayfield,et al.
Particulate Matter and Polycyclic Aromatic Hydrocarbon Determination using a Well-stirred Reactor (Postprint)
,
2003
.
[5]
J. Zelina,et al.
COMBUSTION PARTICULA TES MITIGATION INVES TIGATION USING A WELL -STIRRED REACTOR
,
2002
.
[6]
David L. Stanley,et al.
The Use of Bio-Fuels as Additives and Extenders for Aviation Turbine Fuels
,
1999
.
[7]
Robert L. McCormick,et al.
Combustion of fat and vegetable oil derived fuels in diesel engines
,
1998
.
[8]
Robert O. Dunn,et al.
WINTERIZED METHYL ESTERS FROM SOYBEAN OIL : AN ALTERNATIVE DIESEL FUEL WITH IMPROVED LOW-TEMPERATURE FLOW PROPERTIES
,
1997
.
[9]
J Schwartz,et al.
Particulate air pollution and chronic respiratory disease.
,
1993,
Environmental research.
[10]
Ellen J. Crivella.
Environmental Protection Agency (EPA)
,
1986,
The Bulletin of the Ecological Society of America.