Working principle and construction of centrifugal pumps :
Centrifugal pumps are the most preferred hydraulic pumps used in domestic and industrial world. In this video we will have a conceptual overview of the working of centrifugal pumps.
Impeller - The Heart of Centrifugal Pumps
Centrifugal pumps are used to induce flow or raise pressure of a liquid. Its working is simple. At the heart of the system lies impeller. It has a series of curved vanes fitted inside the shroud plates. The impeller is always immersed in the water. When the impeller is made to rotate, it makes the fluid surrounding it also rotate.
Centrifugal pumps are used to induce flow or raise pressure of a liquid. Its working is simple. At the heart of the system lies impeller. It has a series of curved vanes fitted inside the shroud plates. The impeller is always immersed in the water. When the impeller is made to rotate, it makes the fluid surrounding it also rotate.
Since the rotational
mechanical energy is transferred to the fluid, at the discharge side of the
impeller, both the pressure and kinetic energy of the water will rise. At the
suction side, water is getting displaced, so a negative pressure will be
induced at the eye. Such a low pressure helps to suck fresh water stream into
the system again, and this process continues.
From
foregoing discussions it is clear that, the negative pressure at the eye of the
impeller helps to maintain the flow in the system. If no water is present
initially, the negative pressure developed by the rotating air, at the eye will
be negligibly small to suck fresh stream of water. As a result the impeller
will rotate without sucking and discharging any water content. So the pump
should be initially filled with water before starting it. This process is known
as priming.The impeller is fitted inside a casing.
As a result the water moves out will be collected inside it, and will move in
the same direction of rotation of the impeller, to the discharge nozzle.
Use of
the Casing
From
the illustrations of the pump so far, one specialty of the casing is clear. It
has an increasing area along the flow direction. Such increasing area will help
to accommodate newly added water stream, and will also help to reduce the exit
flow velocity. Reduction in the flow velocity will result in increase in the
static pressure, which is required to overcome the resistance of pumping
system.
Impeller
Design
As
we have discussed earlier impeller is the most vital part of a centrifugal
pump. Successful impellers have been developed with many years of analysis and
developmental work. Fig.4 shows one of such impeller with its one shroud plate
removed for better view of vanes.These vanes are backward
curved. Backward curved vanes have the blade angle less than 90 degree.
Backward curved vanes are the most preferred vane type in the industry due to
its self stabilizing power consumption characteristics. This means with
increase in flow rate power consumption of the pump stabilizes after a limit.
Forward and radial blades are less common in the industry. The eye
configuration of the impeller shown is state of the art. This vane is extracted
from pump model. Such projecting eye section induces better swirl of flow and
guarantees high negative pressure at the suction.
NPSH -
Overcoming the problem of Cavitation
If
pressure at the suction side of impeller goes below vapor pressure of the
water, a dangerous phenomenon could happen. Water will start to boil forming
vapor bubbles. These bubbles will move along with the flow and will break in a
high pressure region. Upon breaking the bubbles will send high impulsive shock
waves and spoil impeller material overtime. This phenomenon is known as
cavitation. More the suction head, lesser should be the pressure at suction
side to lift the water. This fact puts a limit to the maximum suction head a
pump can have.
However Cavitation can be completely avoided by careful
pump selection. The term NPSH (Net Positive Suction Head) helps the designer to
choose the right pump which will completely avoid Cavitation. NPSH is defined
as follows.
Where Pv is vapor pressure of water
V is speed of water at suction side
For a given pumping system it will have an NPSH called 'Available NPSH'. Pump manufacturer will specify the minimum NPSH required for each pump for its safe operation, known as 'Required NPSH'. If the pump needs to work without Cavitation the 'Available NPSH' should be greater than 'Required NPSH'
V is speed of water at suction side
For a given pumping system it will have an NPSH called 'Available NPSH'. Pump manufacturer will specify the minimum NPSH required for each pump for its safe operation, known as 'Required NPSH'. If the pump needs to work without Cavitation the 'Available NPSH' should be greater than 'Required NPSH'
.
Types of Impeller
The
impeller type we have used for the discussion so far is called as an enclosed
type. Here vanes are closed from both the ends with shroud plates. Other types
of impeller which are used in industry are Semi open and open impellers. If the
working fluid is cloggy in nature it is preferred to use an open kind of
impeller. But they are slightly less efficient.
Mechanical
Design Aspects
The
mechanical design of centrifugal pump is always challenging. A shaft is used to
connect between the impeller and motor. Since water pressure inside the casing
is huge, a proper sealing arrangement is imperative in arresting the water
leakage through the shaft casing clearance. Mechanical seal or stuffing box
based mechanism is used for this purpose.Impeller
is mounted on the bearings. But at the suction side of impeller it is not
advisable to fit a bearing, since it will block the flow. As a result the
bearings have to be fitted at the other end. This means impeller is mounted
like a cantilever. For high flow rate pumps, a bearing housing with cooling oil
is necessary for improving the life of the bearings.
Working principle of centrifugal pumps
Reviewed by Admin
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21:23:00
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Reviewed by Admin
on
21:23:00
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