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Abstract

As fuel consumption is a key issue for next-generation internal combustion engines, the heat release rate is increased and the duration shortened towards partially premixed combustion and in extreme cases towards homogeneous charge compression ignition to increase thermal efficiency. However, a steep rise in the heat release rate may trigger pressure oscillations in the combustion chamber, which have shown to increase the heat transfer, lowering efficiency and increasing fuel consumption. The aim of this research is to find the physical mechanisms that cause the increased in-cylinder heat transfer in the presence of pressure oscillations. According to the author’s knowledge, the physical mechanisms responsible for the increased heat transfer have yet not been well understood for this application. Several of the hypotheses for this work are therefore based on the research performed for pulsating turbulent pipe flow. A numerical study has been performed using the large eddy simulation approach, where the pressure oscillations in the combustion chamber have been triggered by an artificially imposed heat source. The results show an increase in heat transfer in relation to pressure amplitude, in accordance with previous experimental studies. The mechanism found is a rapid transport of high-temperature fluid from the heat source towards the wall due to large-scale velocity fluctuations emerged from the pressure oscillations resulting in increased heat transfer.

Keywords

Internal combustion engines pressure oscillations heat transfer computational fluid dynamics large eddy simulation

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References

Vressner

Lundin

Christensen

Tunestål

Johansson

. Pressure oscillations during rapid HCCI combustion. SAE 2003-01-3217, 2003.

Harigaya

Toda

Shigeharu

Hiroshi

. Surface temperature and wall heat flux in a spark-ignition engine under knocking and non-knocking conditions. SAE 891795, 1989.

Enomoto

Kitahara

Takai

. Heat-losses during knocking in a 4-stroke gasoline-engine. JSME Int J B: Fluid T 1994; 37: 668–676.

Ferraro

Marzano

Millo

Bochicchio

. Comparison between heat transfer and knock intensity on a statistical basis. SAE 962101, 1996.

Tsurushima

Kunishima

Asaumi

Aoyagi

Enomoto

. The effect of knock on heat loss in a homogeneous charge compression ignition engines. SAE 2002-01-0108, 2002.

J-H

Ezekoye

Iiyama

Greif

Sawyer

. Effect of knock on time-resolved engine heat transfer. SAE 890158, 1989.

Splitter

Wissink

Hendricks

Ghandhi

Reitz

. Comparison of RCCI, HCCI and CDC operation from low to full load. In: THIESEL, conference on thermo- and fluid dynamic processes in direct injection engines, Valencia, 11–14 September2012.

Lindström

. Methods for characterization of the diesel combustion and emission formation processes. PhD Thesis, KTH Royal Institute of Technology, Stockholm, 2011.

Grandin

Denbratt

. The effect of knock on heat transfer in SI engines. SAE 2002-01-0238, 2002.

10.

Grandin

Denbratt

Bood

. The effect of knock on heat transfer in an SI engine: thermal boundary layer investigation using CARS temperature measurements and heat flux measurements. SAE 2000-01-2831, 2000.

11.

Dec

Keller

. Time-resolved gas temperatures in the oscillating turbulent flow of a pulse combustor tail pipe. Combust Flame 1990; 80: 358–370.

12.

Dec

Keller

Hongo

. Time-resolved velocities and turbulence in the oscillating flow of a pulse combustor pipe. Combust Flame 1991; 83: 271–292.

13.

Dec

Keller

Arpaci

. Heat transfer enhancement in the oscillating turbulent flow of a pulse combustor tail pipe. Int J Heat Mass Tran 1992; 35: 2311–2325.

14.

Richardson

Tyler

. The transverse velocity gradient near the mouths of pipes in which an alternating or continuous flow of air is established. P Phys Soc 1929; 42(1): 1–15.

15.

Habib

Attya

Said

SAM

Eid

Aly

. Heat transfer characteristics and Nusselt number correlation of turbulent pulsating pipe air flows. Heat Mass Transfer 2004; 40(3–4): 307–318.

16.

Eng

. Characterization of pressure waves in HCCI combustion. SAE 2002-01-2859, 2002.

17.

Anderson

. Modern compressible flow: with historical perspective. 3rd ed. New York: McGraw-Hill, 2002.

18.

Grinstein

Margolin

Rider

. Implicit large eddy simulation: computing turbulent fluid dynamics. Cambridge: Cambridge University Press, 2007.

19.

Issa

. Solution of the implicitly discretised fluid flow equation by operator-splitting. J Comput Phys 2004; 62: 40–65.

20.

Torregrosa

Broatch

Margot

Marant

Beauge

. Combustion chamber resonances in direct injection automotive diesel engines: a numerical approach. Int J Engine Res 2004; 5(1): 83–91.

21.

Söder

Prahl-Wittberg

Lindgren

Fuchs

. Compression of a swirling and tumbling flow. In: ASME internal combustion engine division fall technical conference, Dearborn, MI, 13–16 October 2013. New York: ASME.

22.

Örlü

Schlatter

. Comparison of experiments and simulations for zero pressure gradient turbulent boundary layers at moderate Reynolds numbers. Exp Fluids 2013; 54(6): 1–21.

23.

Miles

. Turbulent flow structure in direct-injection swirl supported diesel engines. In: Arcoumanis

Kamimoto

(eds) Flow and combustion in reciprocating engines. Berlin: Springer-Verlag, 2009, pp.173–256.

24.

Howe

. Acoustics of fluid-structure interactions. Cambridge: Cambridge University Press, 1998.

25.

Scholl

Davis

Russ

Barash

. The volume acoustic modes of spark-ignited internal combustion engines. SAE 980893, 1998.

Effect of pressure oscillations on in-cylinder heat transfer – through large eddy simulation

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