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Abstract

The formation and break-up of the tumble in the cylinder were studied in a single-cylinder four-valve spark ignition engine using laser Doppler anemometry (LDA) measurements and multidimensional numerical simulations. The flow structure generated by the tumble break-up was also analysed using the cycle-resolved LDA data processing method. These results show that, during the intake stroke, two counter-rotating vortices are generated in the cylinder by the intake flow along the two sides of the cylinder. They then gradually evolve into the tumble vortex at the initial stage of the compression stroke. Tumble motion can be strengthened by increasing the intake flow going along the surface of the exhaust valves and/or decreasing the intake flow descending directly along the cylinder wall on the side of intake valves. Although a partially decayed tumble vortex still exists in the central part of the combustion chamber near the end of compression, in other parts of the combustion chamber the tumble distorts and breaks up into small vortices and eddies so that the root mean square velocity fluctuation increases. The flow structure generated by the tumble break-up has a characteristic of lower frequency and larger eddy scale.

Keywords

tumble turbulence laser Doppler anemometry measurement spark ignition engine

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References

Le Coz

J. F.

An experimental and computational analysis of the flow field in a four-valve spark engine focus on cycle-resolved turbulence. SAE paper 900056, 1990.

Ando

Characteristics of turbulence generated by tumble and its effect on combustion. COMODIA, 1990, 90, 443–448.

Hadded

Denbratt

Turbulence characteristics of tumbling air motion in four-valve S.I. engines and their correlation with combustion parameters. SAE paper 910478, 1991.

Liu

An experimental study of in-cylinder tumbling motion in a four-valve SI engine by LDA. Trans. CSICE (Chinese Society for Internal Combustion Engine), 1996, 14, 403–409.

Kim

Y.-J.

Lee

S. H.

Cho

N.-H.

Effect of air motion on fuel spray characteristics in a gasoline direct engine. SAE paper 1999-01-0177, 1999.

Fan

Reitz

R. D.

Intake flow simulation and comparison with PTV measurements. SAE paper 1999-01-0176, 1999.

Strokes

Improving the NOx/fuel economy trade-of for gasoline engine with the CCVS combustion system. SAE paper 940488, 1994.

Kuwahara

Watanabe

Optimization of in-cylinder flow and mixing for a center-spark four-valve engine employing the concept of barrel-stratification. SAE paper 940986, 1994.

Kume

Iwamoto

Combustion control technologies for direct injection SI engine. SAE paper 960600, 1996.

10.

Iwamoto

Noma

Yamauchi

Ando

Development of gasoline direct injection engine. SAE paper 970541, 1997.

11.

Roönnbaäuck

Wang

X. L.

Linna

J. R.

Study of inductuation tumble by particle tracking velocimetry in a 4-valve engine. SAE paper 912376, 1991.

12.

Neuber

H. J.

Spiegel

Ganser

Particle tracking velocimetry, a power tool to shape the in-cylinder flow ofmodern multi-valve engine concepts. SAE paper 950102, 1995.

13.

Rouland

Trinite

Particle image velocimetry measurements in a high tumble engine for in-cylinder flow structure analysis. SAE paper 972831, 1997.

14.

Marc

Boree

Tumbling vortex flow in a model square piston compression machine: PIV and LDV measurements. SAE paper 972834, 1997.

15.

Das

Dent

J. C.

Simulation of the mean flow in the cylinder of a motored 4-valve spark engine. SAE paper 952384, 1995.

16.

Liu

T. M.

Santavicca

D. A.

Cycle resolved LDV measurements in motored IC engine. Trans. ASME, J. Fluids Engng, June 1985, 107, 232–240.

17.

Fansler

T. D.

French

D. T.

Cycle-resolved laser-velocimetry measurements in reentrant-bowl-piston engines. SAE paper 880377, 1988.

18.

Liu

Differences between two methods of cycle-resolved analysis and ensemble average in describing turbulence motion in cylinder of an internal combustion engine. Trans. CSICE (Chinese Society for Internal Combustion Engine), 1996, 14, 431–437.

19.

Hirt

C. W.

Amsden

A. A.

Cook

J. C.

An arbitrary Lagrangian-Eulerian computing method. J. Comput. Phys., 1974, 14, 227–253.

20.

Kuo

T.-W.

Multidimensional port-and-cylinder gas flow, fuel spray, and combustion calculations for a port-fuel-injection engine. SAE paper 920515, 1992.

An investigation of in-cylinder tumbling motion in a four-valve spark ignition engine

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