Internal Combustion Engines. Allan T. Kirkpatrick
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(2.73)
since
(2.74)
Assuming ideal gas behavior,
(2.75)
which in differential form is
(2.76)
The energy equation is therefore
(2.77)
differentiating with respect to crank angle, and introducing
(2.78)
Solving for the pressure,
(2.79)
In practice, it is convenient to normalize the equation with the pressure
(2.80)
in which case we obtain
(2.81)
The differential equation for the work is
(2.82)
where
(2.83)
In order to integrate Equations (2.81) and (2.82), an equation for the cylinder volume
(2.84)
upon differentiation,
(2.85)
Equations (2.81) and (2.82) are linear first‐order differential equations of the form
The thermal efficiency is computed directly from its definition
(2.86)
The imep is then computed using Equation (2.87)
(2.87)
For the portions of the compression and expansion strokes before ignition and after combustion, i.e., where
(2.88)
(2.89)
(2.90)
The differential energy equation, Equation (2.79), is also used to compute energy release curves from experimental measurements of the cylinder pressure. This procedure is discussed in detail in Chapter 12. Commercial combustion analysis software is available to perform such analysis in real time during an engines experiment.
The computer program FiniteHeatRelease.m
is listed in the Appendix, and can be used to compare the performance of two different engines with different combustion and geometric parameters. The program computes gas cycle performance by numerically integrating Equation (2.79) for the pressure as a function of crank angle. The integration starts at bottom dead center