Difference between revisions of "Brake Specific Fuel Consumption (BSFC) Maps"
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== '''Brake Specific Fuel Consumption Maps''' == | == '''Brake Specific Fuel Consumption Maps''' == |
Latest revision as of 14:01, 13 July 2018
Note -- for BSFC images missing from this page, see the The BSFC chart thread
Contents
- 1 Note -- for BSFC images missing from this page, see the The BSFC chart thread
- 2 Brake Specific Fuel Consumption Maps
- 3 Cummins 5.9L B5.9-175 diesel
- 4 Cummins 5.9L ISB-235 diesel
- 5 Ford 2.0L Zetec
- 6 Geo Metro 1.0L original
- 7 Geo Metro 1.0L cleaned up
- 8 1st Gen Honda Insight 1.0L
- 9 2017 Mazda 3 Skyactiv gasoline engine
- 10 Mercedes Benz 300SD OM617 5 cylinder turbo diesel
- 11 MG 1.8L B-Series
- 12 Saturn 1.9L DOHC
- 13 Saturn 1.9L DOHC Modified
- 14 Skoda Felicia 1.3L MPI (50kW)
- 15 Subaru EJ22 2.2L SOHC
- 16 Toyota 3.0L V6 1MZ-FE and possibly the 3.0L 3VZ-FE (Previous Engine)
- 17 Toyota 1.8L 1ZZ-FE
- 18 Toyota Prius 1.5L 1NZ-FXE
- 19 Toyota Prius 1.8L 2ZR-FXE 2010-
- 20 Volkswagen 1.4L TSI
- 21 Volkswagen 1.5L diesel
- 22 Volkswagen 2.0L 5 cyl diesel
- 23 Volkswagen Jetta TDI 1.9L ALH 1999.5-2003
- 24 Volkswagen Jetta TDI 2.0L 2009
Brake Specific Fuel Consumption Maps
Useful for determining at what load and rpm your engine is making the most power out of the fuel given to it.
Cummins 5.9L B5.9-175 diesel
Cummins 5.9L ISB-235 diesel
Ford 2.0L Zetec
Geo Metro 1.0L original
File:Geo-1L-bsfc-chart-orig.gif
Geo Metro 1.0L cleaned up
File:Geo-1L-bsfc-chart-reconstruction.gif
1st Gen Honda Insight 1.0L
CVT, which would have lean burn if the car tested was a Japanese-market Insight. Electric assist does not appear to have been accounted for, so the high-load, high-RPM BSFC is grossly underestimated.
On a chassis dyno with a lean burn capable manual transmission equipped vehicle, with no evidence of reduced BSFC at the low load, low RPM regime where lean burn operates:
2017 Mazda 3 Skyactiv gasoline engine
Mercedes Benz 300SD OM617 5 cylinder turbo diesel
MG 1.8L B-Series
BSFC map generated from the information below.
Saturn 1.9L DOHC
File:Saturn 99 1.9l dohc bsfc.jpg
Saturn 1.9L DOHC Modified
File:Saturn 1.9l BSFC cleaned.png
Saturn 1.9L BSFC: Included imperial units, Constant Horsepower curves, Engine Load %, and extrapolated to redline.
Approximate Vacuum readings on Magenta Optimum Efficiency Line:
6.7"hg at 1000 rpm
6.5"hg at 1500 rpm
5.7"hg at 2000 rpm
5.0"hg at 2500 rpm
3.8"hg at 3000 rpm
2.3"hg at 3500 rpm
1.3"hg at 4000 rpm
0.9"hg at 4500 rpm
0.2"hg at 5000 rpm
WOT at >5100 rpm
Skoda Felicia 1.3L MPI (50kW)
Subaru EJ22 2.2L SOHC
Toyota 3.0L V6 1MZ-FE and possibly the 3.0L 3VZ-FE (Previous Engine)
File:Toyota 1mzfe 3.0l bsfc.JPG
Toyota 1.8L 1ZZ-FE
Toyota Prius 1.5L 1NZ-FXE
File:Toyota 1nzfxe prius bsfc.jpg
Toyota Prius 1.8L 2ZR-FXE 2010-
File:Toyota 2zrfxe 1.8l prius bsfc2.jpg
Volkswagen 1.4L TSI
There was an article on VW's cylinder deactivating TSI in a magazine (Serwis motoryzacyjny, 11/2011) and it had the following BSFC graph, illustrating an example of how cylinder deactivation can help reduce fuel consumption.
The red line '1' graphs constant engine power, in this example 30kW. By going to an rpm and load closer to the BSFC sweetspot the fuel consumption can be lowered by 20%. Deactivating half of the cylinders helps to increase the load, but among the things the article didn't state are: Is that BSFC for the engine in 4-, or 2-cylinder mode? Or maybe combined? What would be the effect of only shifting gears? What would be the effect of only deactivating 2 cylinders?
Anyhow, the article claimed that only deactivating the cylinders reduced fuel consumption by 0.4 l/100km in the NEDC cycle, while with the Start/Stop system 0.6 l/100km. At steady, low speeds and loads the fc can be reduced by 0.7-1.0 l/100km. The cylinders are deactivated when engine speed is between 1400 and 4000 rpm, and torque between 25 and 75 Nm (the max torque is 250 Nm).
Volkswagen 1.5L diesel
Volkswagen 2.0L 5 cyl diesel
Volkswagen Jetta TDI 1.9L ALH 1999.5-2003
File:ALH BSFC map with power hyperbolae.png
Each curve represents a constant horsepower developed by the engine. If you are driving on a given road with a constant grade, speed, and ambient conditions, regardless of which gear you are in, it requires roughly the same amount of power to overcome aerodynamic drag, rolling resistance and driveline losses. Therefore, regardless of what gear you're in, you're riding anywhere along the same blue curve; exactly where you sit on that blue curve being only dependent on the gear you're in and therefore the RPM at which the engine is turning over.
In the case of the TDI BSFC chart, if I take the example of operating on a certain speed such that the power is 20 HP, the lowest BSFC occurs when running at the gear that corresponds to about 1250 RPM. If I run at either a higher- or lower RPM from this point, my BSFC will increase. This is about the only point in the entire engine map where it would be disadvantageous to operate at an even higher gear if one were available (lower RPM) because of the worsening BSFC. Almost everywhere else, the lowest BSFC is achieved at the lowest possible RPM at a given power.