Simulation of internal combustion engine heat transfer using low-dimensional thermodynamic modeling often relies on quasisteady heat transfer correlations. However, unsteady thermal boundary layer modeling could make a useful contribution because of the inherent unsteadiness of the internal combustion engine environment. Previous formulations of the unsteady energy equations for internal combustion engine thermal boundary layer modeling appear to imply that it is necessary to adopt the restrictive assumption that isentropic processes occur in the gas external to the thermal boundary layer. Such restrictions are not required and we have investigated if unsteady modeling can improve the simulation of crank-resolved heat transfer. A modest degree of success is reported for the present modeling, which relies on a constant effective turbulent thermal conductivity. Improvement in the unsteady thermal boundary layer simulations is expected in the future when the temporal and spatial variations in effective turbulent conductivity are correctly modeled.

1.
Borman
,
G.
, and
Nishiwaki
,
K.
, 1987, “
Internal-Combustion Engine Heat Transfer
,”
Prog. Energy Combust. Sci.
0360-1285,
13
, pp.
1
46
.
2.
Annand
,
W. J. D.
, 1963, “
Heat Transfer in the Cylinders of Reciprocating Internal Combustion Engines
,”
Proc. Inst. Mech. Eng.
0020-3483,
177
(
36
), pp.
973
990
.
3.
Isshiki
,
N.
, and
Nishiwaki
,
N.
, 1970, “
Study on Laminar Heat Transfer of Inside Gas With Cyclic Pressure Change on an Inner Wall of a Cylinder Head
,”
Heat Transfer 1970: Proceedings of the Fourth International Heat Transfer Conference
, Paris and Versailles,
U.
Grigull
and
E.
Hahne
, eds.,
Elsevier
,
Amsterdam
, pp.
1
10
, Paper No. FC3.5.
4.
Lawton
,
B.
, 1987, “
Effect of Compression and Expansion on Instantaneous Heat Transfer in Reciprocating Internal Combustion Engines
,”
Proc. Inst. Mech. Eng., Part A
0957-6509,
201
(
A3
), pp.
175
186
.
5.
Yang
,
J.
, and
Martin
,
J. K.
, 1989, “
Approximate Solution—One-Dimensional Energy Equation for Transient, Compressible, Low Mach Number Turbulent Boundary Layer Flows
,”
ASME J. Heat Transfer
0022-1481,
111
, pp.
619
624
.
6.
Anderson
,
J. D.
, 1990,
Modern Compressible Flow (With Historical Perspective)
, 2nd ed.,
McGraw-Hill
,
New York
.
7.
White
,
F. M.
, 1991,
Viscous Fluid Flow
, 2nd ed.,
McGraw-Hill
,
New York
.
8.
Buttsworth
,
D. R.
, 2002, “
Spark Ignition Internal Combustion Engine Modelling Using Matlab
,” Faculty of Engineering and Surveying Technical Reports, University of Southern Queensland, Report No. TR-2002-02.
9.
Ferguson
,
C. R.
, 1986,
Internal Combustion Engines, Applied Thermosciences
,
Wiley
,
New York
.
10.
Olikara
,
C.
, and
Borman
,
G. L.
, 1975, “
Calculating Properties of Equilibrium Combustion Products With Some Applications to I.C. Engines
,” SAE Paper No. 750468.
11.
Buttsworth
,
D. R.
, 2001, “
A Finite Difference Routine for the Solution of Transient One Dimensional Heat Conduction Problems With Curvature and Varying Thermal Properties
,” Faculty of Engineering and Surveying Technical Reports, University of Southern Queensland, Report No. TR-2001-01.
12.
Wu
,
Y. -Y.
,
Chen
,
B. -C.
, and
Hsieh
,
F. -C.
, 2006, “
Heat Transfer Model for Small-Scale Air-Cooled Spark-Ignition Four-Stroke Engines
,”
Int. J. Heat Mass Transfer
0017-9310,
49
, pp.
3895
3905
.
You do not currently have access to this content.