Fundamentals of Heat Engines. Jamil Ghojel
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Referring to Figure 1.2, the force required to accelerate mass dm at P is dF = atdm and the moment required to accelerate the same mass is dM = r at dm.
The resultant moment needed to accelerate the total mass of the rotating rigid body is
For a constant angular acceleration,
(1.11)
where I = ∫ r2 dm is the moment of inertia of the whole mass of the rigid body rotating about an axis passing through 0. Equation (1.11) indicates that if the body has rotational motion and is being acted upon by moment M, its moment of inertia I is a measure of the resistance of the body to angular acceleration α. In linear motion, the mass m is a measure of the resistance of the body to linear acceleration a when acted upon by force F.
In planar kinetics, the axis chosen for analysis passes through the centre of mass G of the body and is always perpendicular to the plane of motion. The moment of inertia about this axis is IG. The moment of inertia about an axis that is parallel to the axis passing through the centre of mass is determined using the parallel axis theorem
(1.12)
where d is the perpendicular distance between the parallel axes.
For a rigid body of complex shape, the moment of inertia can be defined in terms of the mass m and radius of gyration k such that I = mk2, from which
(1.13)
1.1.6 Moment, Couple, and Torque
The moment of force F about a point 0 is the product of the force and the perpendicular distance L of its line of action from 0 (Figure 1.3a):
(1.14)
Figure 1.3 Definitions of moment, couple, and torque.
A couple is a pair of planar forces that are equal in magnitude, opposite in direction, and parallel to each other (Figure 1.3b). Since the resultant force is zero, the couple can only generate rotational motion. The moment of the couple is given by
(1.15)
Torque is also a moment and is given by Eq. (1.14), but is used mainly to describe a moment tending to turn or twist a shaft of reciprocating and gas turbine engines, motors, and other rotating machinery. In machinery such as engines, force F will be applied to the arm L at a right angle (θ = 0). In these applications, the power is often expressed in terms of the torque (see Eqs. 1.21 and 1.22 in Section 1.1.9).
Figure 1.4 Kinetics of rotating shaft: (a) accelerating shaft; (b) decelerating shaft.
1.1.7 Accelerated and Decelerated Shafts
Consider a shaft carrying a gas turbine rotor or piston engine flywheel with the moments and torques acting as shown in Figure 1.4. A heat engine is usually started by means of an external driver such as starting motor by accelerating the driving shaft from rest to the required speed. The driving torque required to accelerate the shaft Td is balanced by the inertia couple Mi = Iα (α is angular acceleration) and resistance couple MR, which is mainly due to friction in the bearings, as shown in Figure 1.4a. The governing equation is
(1.16)
To stop an engine, a braking torque Tb is applied, which is assisted by the resistance moment Mr to decelerate the shaft from the rated speed to rest, as shown in Figure 1.4b The governing equation is
(1.17)
The engine can be brought to rest without applying a braking torque by cutting off the fuel supply and allowing the resistance couple to decelerate the shaft to rest. Note that when the shaft is decelerating, the angular acceleration vector is counter to the direction of rotation of the shaft.
1.1.8 Angular Momentum (Moment of Momentum)
The angular momentum of body about an axis is the moment of its linear momentum about the axis. Figure 1.5 shows a body rotating with angular velocity ω about an axis passing through 0 (perpendicular to the plane of the page):
Linear momentum of particle of mass dm = dm ωl
Moment of momentum of particle about 0 = dm ωl2
Total momentum H0 of the body about 0 for constant angular velocity(1.18)
If G is the centre of gravity of the body,
(1.19)
and the angular momentum of the body can be written as
(1.20)