Power Plant Engineering


 PRINCIPLE OF OPERATION OF STEAM TURBINE


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6.1. PRINCIPLE OF OPERATION OF STEAM TURBINE
The principle of operation of steam turbine is entirely different from the steam engine. In recip-
rocating steam engine, the pressure energy of steam is used to overcome external resistance and the
dynamic action of steam is negligibly small. But the steam turbine depends completely upon the dy-
namic action of the steam. According to Newton’s Second Law of Motion, the force is proportional to
the rate of change of momentum (mass × velocity). If the rate of change of momentum is caused in the
steam by allowing a high velocity jet of steam to pass over curved blade, the steam will impart a force to
the blade. If the blade is free, it will move off (rotate) in the direction of force. In other words, the motive
power in a steam turbine is obtained by the rate of change in moment of momentum of a high velocity jet
of steam impinging on a curved blade which is free to rotate. The steam from the boiler is expanded in
a passage or nozzle where due to fall in pressure of steam, thermal energy of steam is converted into
kinetic energy of steam, resulting in the emission of a high velocity jet of steam which, Principle of
working impinges on the moving vanes or blades of turbine (Fig. 6.1).
C
1
C
2
Force
Blade
Fig. 6.1. Turbine Blade.
Attached on a rotor which is mounted on a shaft supported on bearings, and here steam under-
goes a change in direction of motion due to curvature of blades which gives rise to a change in momen-


196
POWER PLANT ENGINEERING
tum and therefore a force. This constitutes the driving force of the turbine. This arrangement is shown.
It should be realized that the blade obtains no motive force from the static pressure of the steam or from
any impact of the jet, because the blade in designed such that the steam jet will glide on and off the blade
without any tendency to strike it.
As shown in Fig. 6.2, when the blade is locked the jet enters and leaves with equal velocity, and
thus develops maximum force if we neglect friction in the blades. Since the blade velocity is zero, no
mechanical work is done. As the blade is allowed to speed up, the leaving velocity of jet from the blade
reduces, which reduces the force. Due to blade velocity the work will be done and maximum work is
done when the blade speed is just half of the steam speed. In this case, the steam velocity from the blade
is near about zero i.e. it is trail of inert steam since all the kinetic energy of steam is converted into work.
The force and work done become zero when the blade speed is equal to the steam speed. From the above
discussion, it follows that a steam turbine should have a row of nozzles, a row of moving blades fixed to
the rotor, and the casing (cylinder). A row of nozzles and a raw of moving blades constitutes a stage of
turbine.
Nozzle
Entering velocity
= C
1
Blade velocity
u = 0
F
Blade
locked
Leaving
velocity = C
2
(
)
b1
C
1
C
2
(
)
b2
u = C /4
1
u = C /2
1
C
1
C = 0

(
)
b3
F

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