We were discussing a new topic, in the subject of
fluid mechanics and hydraulics machine, i.e. an
introduction to hydraulic machine, various
types of hydraulic turbines and some important terminologies
associated with a hydraulic turbine such as Gross
head, Net head and efficiencies of a hydraulic turbine. Â
We have also seen the fundamental
of Pelton wheel or Pelton hydraulic turbine, basics
of radial flow reaction turbines, difference
between inward radial flow reaction turbine and outward radial flow reaction
turbine, Francis
turbine, Axial
flow reaction turbine, Specific speed of turbine, Draft-tube
and basics of Governing of turbines in our recent posts.Â
Today we will understand here the governing of Pelton
turbine or Impulse turbine with the help of this post. So, lets see governing of Pelton turbine.Â
Before going to understand the governing of Pelton turbine, We must recall that hydraulic turbines are basically defined as the hydraulic machines which convert hydraulic energy in to mechanical energy and this mechanical energy will be given to a generator to produce the electric energy. Generator will be directly coupled with the hydraulic turbine.Â
Before going to understand the governing of Pelton turbine, We must recall that hydraulic turbines are basically defined as the hydraulic machines which convert hydraulic energy in to mechanical energy and this mechanical energy will be given to a generator to produce the electric energy. Generator will be directly coupled with the hydraulic turbine.Â
In order to maintain the constant frequency of
electric power output, the rotor of the turbine has to rotate with a constant
speed and therefore it is needed to maintain the constant rotational speed of
the turbine rotor.Â
The process by which the speed of rotation of
turbine rotor is kept constant will be termed as governing of a turbine and it
is well discussed in our previous post. So let us directly come to the point to
find out the governing of Pelton turbine or impulse turbine.Â
First, we need to do the governing of turbine in such a way that it should not alter the operating parameters of turbine otherwise efficiency of turbine will be reduced.Â
Second, there should not be any water hammer problems during governing of turbine.Â
Important points to consider while governing of turbineÂ
There are two very important points that we have to consider while governing of turbine.ÂFirst, we need to do the governing of turbine in such a way that it should not alter the operating parameters of turbine otherwise efficiency of turbine will be reduced.Â
Second, there should not be any water hammer problems during governing of turbine.Â
Governing of Pelton turbineÂ
Oil pressure governor is used for governing of
Pelton turbine. Oil pressure governor, as displayed here in following figure, will
have following components.
- Oil sump
- Oil pump
- Servomotor or relay cylinder
- Control valve or distribution valve or relay valve
- Centrifugal governor or pendulum
- Piping arrangements
- Spear rod or needle
Gear pump is used here as oil pump in the oil
pressure governor. Gear pump will be driven by the power obtained from the
turbine shaft.
Centrifugal governor or pendulum will be connected
with the turbine main shaft with the help of belt or gear.Â
Piping arrangements will connect the oil sump with
the control valve and control valve to servomotor or relay cylinder.Â
Following figure displayed here indicates the position
of the piston in the relay cylinder, position of control valve or relay valve
and fly balls of centrifugal governor, when the turbine is running at the
normal speed.Â
Let us discuss here the case when electrical load
decreases or increases due to change in demand. We will see here how the
governor will work to maintain the rotational speed of the rotor constant.Â
Case 1: Electrical Load decreasesÂ
When the electrical load decreases, resisting torque
will also be reduced. Therefore for a given driving torque, rotational speed of
the rotor of turbine will be increased. As centrifugal governor will be
connected with the turbine main shaft with the help of fan or gear, rotational speed
of governor will also be increased.Â
Due to the increase in rotational speed of the centrifugal
governor, centrifugal force acting on the fly-balls will be increased and fly-balls
will move in upward direction.Â
Sleeve will also move in upward direction due to the
movement of fly-balls in upward direction.
As we can see here in figure, there is a horizontal
lever which is supported over a fulcrum and connects the sleeve and piston rod
of control valve.Â
Once sleeve will move in upward direction,
horizontal lever will turn about the fulcrum and hence piston rod of control
valve will move in downward direction. Due to the movement of piston rod of
control valve towards downward, V1 valve will be closed and V2
valve will be opened.Â
Gear pump will suck the oil from oil sump and discharge
oil under pressure to the control valve. Oil under pressure will flow through
the valve V2 to servomotor or relay cylinder and will exert the
pressure force at face A of piston of relay cylinder. Therefore, piston along
with piston rod and spear will move towards right.Â
Due to the movement of piston along with piston rod
and spear towards right, area of flow of water at the outlet of nozzle will be
reduced and hence flow rate of water to the turbine will also be reduced.
Speed of rotation of rotor of turbine will be
reduced due to the reduction in flow rate of water to the turbine.Â
The fly-balls, sleeve, lever and piston rod of control
valve will come to its original position when the speed of rotation of rotor of
turbine becomes normal.Â
Case 2: Electrical Load decreasesÂ
When the electrical load increases, resisting torque
will also be increased. Therefore for a given driving torque, rotational speed
of the rotor of turbine will be decreased. As centrifugal governor will be
connected with the turbine main shaft with the help of fan or gear, rotational speed
of governor will also be decreased.Â
Due to the decrease in rotational speed of the centrifugal
governor, centrifugal force acting on the fly-balls will be decreased and fly-balls
will move in downward direction.
Sleeve will also move in downward direction due to
the movement of fly-balls in downward direction.Â
Once sleeve will move in downward direction,
horizontal lever will turn about the fulcrum and hence piston rod of control
valve will move in upward direction. Due to the movement of piston rod of
control valve towards upward direction, V1 valve will be opened and
V2 valve will be closed.Â
Gear pump will suck the oil from oil sump and discharge
oil under pressure to the control valve. Oil under pressure will flow through
the valve V1 to servomotor or relay cylinder and will exert the
pressure force at face B of piston of relay cylinder. Therefore, piston along
with piston rod and spear will move towards left.Â
Due to the movement of piston along with piston rod
and spear towards left, area of flow of water at the outlet of nozzle will be increased
and hence flow rate of water to the turbine will also be increased.Â
Speed of rotation of rotor of turbine will be increased
due to increase in flow rate of water to the turbine.Â
The fly-balls, sleeve, lever and piston rod of control
valve will come to its original position when the speed of rotation of rotor of
turbine becomes normal.Â
As we have already studied that in order to maintain
the constant frequency of electric power output, the rotor of the turbine has
to rotate with a constant speed and therefore it is needed to maintain the
constant rotational speed of the turbine rotor.Â
This is the mechanism of oil pressure governor that
control the flow rate of water to the turbine according to the electrical load in
order to maintain the constant rotational speed of the turbine rotor.Â
Do you have any suggestions? Please write in comment
box.Â
Further we will find out, in our next post,
governing of Reaction turbine.Â
You Should also find out some important posts those are very useful and must need to read. Â
- Reactions at support and connection in engineering mechanicsÂ
- Force system Â
- Truss in engineering mechanics Â
- Process to solve the truss problems Â
- Method of joints Â
- Method of sections Â
- Concept of force system Â
- Principle of transmissibility of forces Â
- Classification of force system Â
- Body force and surface force Â
- Moment of a force Â
- Varignon’s theorem Â
- Concept of a couple Â
- Resultant of a force system acting on a body Â
- How to draw the Free body diagramÂ
Reference:Â
Fluid mechanics, By R. K. BansalÂ
Image courtesy: Google Â
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