Encyclopedia > Specific fuel consumption

  Article Content

Specific fuel consumption

Specific fuel consumption, often shortened to SFC, is an engineering term that is used to describe the fuel effeciency of an engine design. It measures the amount of fuel needed to provide one horsepower for a period of one hour, typically in pounds of fuel burned.

SFC is dependent on the engine design, with differences in the SFC between different engines tending to be quite small. For instance, typical gasoline engines will have a SFC of about 0.5 lb/hp/hr, regardless of the design of a particular engine. One exception to the rule is that the SFC within a particular class of engine will vary based on the compression ratio, an engine with a higher compression ratio will deliver a better SFC because it extracts more power from the fuel. Diesel engines have better SFCs than gasoline largely because they have much higher compression ratios, the way they burn their fuel is actually less effecient.

Modern jet engines actually have much higher compression ratios than piston engines, which was not always the case. Whereas a good Diesel might have a compression ratio of 22:1, Rolls-Royce RB-211 developed for the L-1011[?] in the 1960s runs at 29:1, and the latest R-R Trent runs at 41:1. Nevertheless jets deliver considerably worse SFC, which is due to their compressors being much less effecient than a piston for most pressure ranges.

Engine type SFC
Ramjet 1.0 lb/hp/hr
Turbo-prop 0.8 lb/hp/hr
Otto cycle 0.5 lb/hp/hr
Diesel cycle 0.4 lb/hp/hr
Otto-Compound engine 0.38 lb/hp/hr
Turbocharged Diesel 0.38 lb/hp/hr
Turbocharged & Intercooled Diesel 0.36 lb/hp/hr
Diesel-Compound engine 0.34 lb/hp/hr



All Wikipedia text is available under the terms of the GNU Free Documentation License

 
  Search Encyclopedia

Search over one million articles, find something about almost anything!
 
 
  
  Featured Article
Dynabee

... axis and the groove rims will accelerate or brake the spinning gyroscope, with a maximum effect when the axis starts "rolling" inside the groove. (Compare with graphic ...

 
 
 
This page was created in 34.1 ms