Vibration behaviour of an internal combustion engine depends on rigid body inertial
dynamics, structural modal characteristics of its elastic members, tribological behaviour of loadbearing
contacts, and piston-cylinder interactions. Therefore, it is essential to use a multi-physics
approach that addresses all these physical properties in a single integrative model as presented
in this paper. This approach can be regarded as holistic and a good aid for detailed design. Particular
attention is paid to the critical elements in the system, such as load-bearing conjunctions
(crankshaft main bearings) and piston-cylinder wall interactions. Another important feature is
the integrated analysis across the physics of motion from microscale fluid film formation to
submillimetre structural deformations and onto large displacements of inertial members. In
order to succeed in predictions within sensible industrial time scales, analytical methods have
been used as far as possible rather than numerical approaches. Model predictions show good
agreement with fired engine test data.
History
School
Mechanical, Electrical and Manufacturing Engineering
Citation
PERERA, M.S.M., THEODOSSIADES, S. and RAHNEJAT, H., 2007. A multi-physics multi-scale approach in engine design analysis. Proceedings of the Institution of Mechanical Engineers, Part K: Journal of Multi-body Dynamics, 221(3), pp. 335-348.