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Internal Combustion Engines. Allan T. Kirkpatrick
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Название: Internal Combustion Engines

Автор: Allan T. Kirkpatrick

Издательство: John Wiley & Sons Limited

Жанр: Физика

Серия:

isbn: 9781119454557

isbn:

СКАЧАТЬ alt="images"/> is

(1.33) equation

For images , we can expand the images term in a Taylor series,

(1.34) equation

(1.35) equation

As images , the approximate volume images can then be expressed as a function only of the compression ratio images :

(1.36) equation

The cylinder volumes predicted by Equations (1.33) and (1.36) are compared in Figure 1.11 for a value of images , using the Matlab® program Volume.m listed in the Appendix. Both equations give identical results at bottom dead center and top dead center. The approximate volume relation underpredicts the exact cylinder volume by about 18% at images 59 degrees near the middle of the stroke.

Graph depicts the cylinder volume versus crank angle for r=10,ε=1/3.

Figure 1.11 Cylinder volume vs. crank angle for

(Equations 1.33 and 1.36).

The instantaneous piston velocity images can be found by replacing images with images and differentiating Equation (1.32) with respect to time images giving

(1.37) equation

Equation (1.37) can be nondimensionalized by the mean piston speed images , resulting in

(1.38) equation

Using the Matlab® program Velocity.m listed in the Appendix, the nondimensional velocity images is plotted versus crank angle from top dead center (tdc) to bottom dead center (bdc) in Figure 1.12 for a value of images . The piston velocity is zero at tdc and bdc. Due to the geometry of the slider crank mechanism, the velocity profile is nonsymmetric. For this example, the maximum nondimensional velocity images = 1.65 occurs at images = 72 images after tdc.

Graph depicts the nondimensional velocity vs. crank angle for ε=1/3.

Figure 1.12 Nondimensional velocity vs. crank angle for

(Equation 1.38).

If we neglect terms of images , and use the trigonometric identity images , the piston velocity can be approximated as

(1.39) equation

The acceleration images is found by differentiating Equation (1.39) with respect to time

(1.40) equation

Note that the velocity and acceleration terms have two components, one varying with the same frequency images as the crankshaft, known as the primary term, and the other varying at twice the crankshaft frequency images , known as the secondary term. In the limit of an infinitely long connecting rod, i.e., images , the motion reduces to a simple harmonic at a frequency images .

The reciprocating motion of the connecting rod and piston creates accelerations and thus inertial forces and moments that need to be considered in the choice of an engine configuration. In multicylinder engines, the cylinder arrangement and firing order are chosen to minimize the primary and secondary forces and moments. Complete cancellation is possible for the following four‐stroke engines: in‐line 6‐ and 8‐cylinder engines; horizontally opposed 8‐ and 12‐cylinder engines, and 12‐ and 16‐cylinder V engines (Taylor 1985).

Scaling of Engine Performance

The performance characteristics of three different diesel engines are compared in Table 1.1. The engines are a four‐cylinder 1.9 L automobile engine, a six‐cylinder 5.9 L truck engine, and a six‐cylinder 7.2 L military engine. Comparison of the data in the table indicates that the performance characteristics of piston engines are remarkably similar when scaled to be СКАЧАТЬ

Internal Combustion Engines. Allan T. Kirkpatrick Чтение книги онлайн.

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Scaling of Engine Performance

Internal Combustion Engines. Allan T. Kirkpatrick
Чтение книги онлайн.