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The First Law of Thermodynamics has been applied to the analysis of the dynamometer performance of a 2.0 litre,115 PS, common rail, turbocharged, automotive diesel engine operating under steady state conditions. Validation of the method is presented with correlation between the input fuel power and summed loss terms shown to be better than 3%. The study was conducted over a matrix of engine speed-load sites and maps of the underlying trends and magnitudes are presented. Detailed analysis of the relative heat balance contributions at a range of loads at fixed engine, water pump, and oil pump speeds is also presented. The proportions of heat rejected to the different primary paths (i.e. brake, coolant, oil, charge cooler, exhaust, and external) were found to vary with engine speed and load. Also, friction power was found to vary principally as a function of engine speed with some small dependency on engine load.

In this paper, data are presented showing how lubricant properties affect the heat flux, oil flow rates and temperatures within a turbocharged diesel passenger car engine. The oils tested cover a range of viscosities and base oil types. Mono-grades were used to remove the effect of shear thinning. The effect of viscosity modification was also examined. Lowest viscosity lubricants resulted in the lowest sump temperatures. More fuel was required to produce the same brake output from the engine with thicker oils. Engine oil heat rejection increased with viscosity, not just in absolute terms, but also as a fraction of the total heat loss. Viscosity does affect oil temperature through increased total heat from friction, and also through its effect on heat transfer. In addition, oil viscosity is itself dependent on operating temperature. Heat transfer theory suggests a relation between mass flow rate and heat transfer.

This paper questions whether the application of steady speed volumetric efficiency data to transient SI engine operation under WOT is a valid one. A state-of-the-art computer simulation model is used to compare steady speed volumetric efficiency with instantaneous values. A baseline engine model is first correlated with measured volumetric efficiency data to establish confidence in the engine model's predictions. A derivative of the baseline model, complete with variable geometry inlet manifold, is then subjected to a transient excursion simulating typical, in-service, maximum rates of engine speed change. Instantaneous volumetric efficiency, calculated over discrete engine cycles forming the sequence, is then compared with its steady speed counterpart at the corresponding speed. It is shown that the engine volumetric efficiency responds almost quasi-steadily under transient operation thus justifying the assumption of correlation between steady speed and transient data.

Time-domain numerical modelling of performance for complete engine systems is now routine in most automotive design offices. To achieve this with a minimal computer run-time overhead, drastic simplification of the exhaust silencer box models is required. Complete exhaust systems are often modelled as simple capacitances bounded by orifices. This is justified on the grounds that the influence of exhaust system geometric detail on the engine torque-speed characteristic is less significant than that of the backpressure of the ‘lumped’ system. In contrast to engine performance, acoustic modelling of silencer boxes is usually carried out in the frequency-domain, since this offers a computationally cost-effective means of including very complex internal geometries with minimal computer time overhead. One limitation of these models is the difficulty of characterising the engine as an acoustic source, though empirical methods are often employed.