International Journal of I.C. Engines and Gas Turbines

Stringent emission from the conventional vehicles draws attention of automobile researches to develop engine either high fuel efficiency and low emission of NOx, CO and unburnt hydrocarbons. Hence, there by Homogeneous charge compression ignition came to the effect. Homogeneous charge compression ignition engine is the type of engine the well organised mixture of air and fuel ratio enters into the combustion chamber, and it is compressed up to auto-ignited temperature and there by combustion takes place. HCCI combines the characteristics of both SI and CI engine. In the current study, we will discuss about the performance parameters of the HCCI engine like Pressure, Temperature, Turbulent kinetic viscosity and swirl inside the cylinder at three different speed 1000, 2000, 3000 rpms through CFD analysis. The modelling of each part like cylinder, piston, Intake manifold and exhaust manifold in CATIA v5 and Computational fluid dynamics analysis was performed on STAR CCM+ by using large eddy simulational (LES) model. As we discussed about the combustion parameters pressure, temperature, Turbulent kinetic viscosity, swirl and identified behaviour of those parameters at suction, compression, expansion and exhaust in four stroke single cylinder diesel engine at 1000rpm,2000rpm and 3000rpm.The graphs are drawn between parameters with respect to crank angle as pressure vs crank angle, temperature vs crank angle, turbulent kinetic viscosity vs crank angle, swirl vs crank angle. The maximum a pressure obtained at 2000 rpm which is 57 bar, Maximum temperature obtained at 3000 rpm which is 1399.3 k, maximum turbulent kinetic viscosity at the speed of 3000 rpm in the exhaust process is 8424.3 j/kg. The maximum swirl obtained at 3000 rpm

Homogeneous charge compression ignition engine, CFD, LES model, StarCCM+, pressure, Temperature, Turbulent kinetic viscosity, Swirl.

Abani N., Munnanur A., Reitz R. D., 2008, - Reduction of numerical parameters dependencies in

diesel spray models II. Journal of engineering for gas turbines and power, ASME, vol.130,032809-

-032809-9.

Djavareshkirn M. H. and Ghasemi A.,2009, -Investigation of jet break-up process in diesel engine

spray model II, Journal of Applied Sciences, Vol.9, no.11, pp 2078-2087 Bianchi G.M., Pelloni P.,

Corcione F.E., Allocca L., Luppino F., 2001, ‖ Modelling Atomization of high pressure diesel

sprays‖, Journal of engineering for Gas Turbines and Power, ASME, vol.123,pp 419-427.

Bianchi G.M., pelloni p., Corcione F.E., Allocca L., Luppino F., 2001, II Modelling Atomization

of high pressure diesel sprays II , Journal of engineering for Gas Turbines and Power , ASME ,

vol.123,pp 419-427.

Hountalas D.T., Kourmenos D.A., Mavropoulos G.c., Binder K.B and Schwarz V., 2004,-

Multizone combustion modelling as a tool for DI engine development Application for the effect of

injection pressure II. SAE, Vol.1, 2004-01-0115

Hegart C., Barths H. and Peters N., 1999, -Modeling nad combustion in a smallbore diesel engien

using a method based on Represenatative Interactive Flaments II. SAE, vol.1, pp 4555.

Kasocsa A., Tatschl R. and Kristof G., 2007, - page 35 Analysis of spray evolution in internal

combustion engine using numerica simulations II. Jounal of computational and Applied mechanics,

Vol. no. 8, pp 85-100.

I.C Internal Combustion Engines | 4th Edition textbook. 1 July 2017 by V.Ganeshan.

Introduction to large eddy simulation of Turbulent Flows, J Frohlich,W.Rodi Institute of

Hydromechanics, university of Karlsruhe, Kaiserstrabe, karlsruhe, Germany.

CFD analysis on Petrol Internal combustion engine, Mahamoud A.Mashkour Mustafa Hadi

Ibraheem, Mechanical Engineering Department University of Technology, Bhagdad, Iraq. II

Journal of university of Babylon for Engineering Sciences Vol(26), No(9):2018

K.M.Ravichandra, D.Manikanta, M. kotesh.”CFD simulation of an engine by producer of gas

“International Journal of civil Engineering and Technology (IJCIET),volume8,issue 10,october

HEYWOOD, J.B., Internal combustion engine fundamentals. New York, MC GRAW-HILL,1988

Krishna Adepalli, Mallikarjuna J.M. “parametric analysis on 4-stroke GDI using CFD”. Alexendria

Engineering Journal.2016.

T. Morauszki, P.Mandli,Z.Harvorth and M.R.Dreyer.”Simulation of Fluid Flow combustion and

Heat transfer in Internal Combustion Engine”. Hungarian journal of Industrial Chemistry Vol39 (1)

pp.27-30-2011.