A Little Bit More About Cavitation 9-10
McNally
Institute
Cavitation means different things to different people. It
has been described as:
- A reduction in pump capacity.
- A reduction in the head of the pump.
- The formation of bubbles in a low pressure area of the
pump volute.
- A noise that can be heard when the pump is running.
- Damaged that can be seen on the pump impeller and volute.
- Just what then is this thing called cavitation? Actually
it is all of the above. In another section of this series
I described the several types of cavitation, so in this paper
I want to talk about another side of cavitation and try to
explain why the above happens.
Cavitation implies cavities or holes in the fluid we are
pumping. These holes can also be described as bubbles, so cavitation
is really about the formation of bubbles and their collapse.
Bubbles form when ever liquid boils. Be careful not to associate
boiling with hot to the touch. Liquid oxygen will boil and
no one would ever call that hot.
Fluids boil when the temperature of the fluid gets too hot
or the pressure on the fluid gets too low. At an ambient sea
level pressure of 14.7 psia (one bar) water will boil at 212°F.
(100°C) If you lower the pressure on the water it will boil
at a much lower temperature and conversely if you raise the
pressure the water will not boil until it gets to a higher
temperature. There are charts available to give you the exact
vapor pressure for any temperature of water. If you fall below
this vapor pressure the water will boil. As an example:
| Fahrenheit |
Centigrade |
Vapor pressure lb/in2 A |
Vapor pressure (Bar) A |
| 40 |
4.4 |
0.1217 |
0.00839 |
| 100 |
37.8 |
0.9492 |
0.06546 |
| 180 |
82.2 |
7.510 |
0.5179 |
| 212 |
100 |
14.696 |
1.0135 |
| 300 |
148.9 |
67.01 |
4.62 |
Please note that I am using absolute not gauge pressure.
It is common when discussing the suction side of a pump to
keep everything in absolute numbers to avoid the use of minus
signs. So instead of calling atmospheric pressure zero, we
say one atmosphere is 14.7 psia at seal level and in the metric
system the term commonly used is one bar, or 100 kPa if you
are more comfortable with those units.
Now we will go back to the first paragraph and see if we
can clear up some of the confusion:
The capacity of the pump is reduced
- This happens because bubbles take up space and you cannot
have bubbles and liquid in the same place at the same time.
- If the bubble gets big enough at the eye of the impeller,
the pump will lose its suction and will require priming.
The head is often reduced
- Bubbles unlike liquid are compressible. It is this compression
that can change the head.
The bubbles form in a lower pressure area because they cannot
form in a high pressure area.
- You should keep in mind that as the velocity of a fluid
increase, the pressure of the fluid decreases. This means
that high velocity liquid is by definition a lower pressure
area. This can be a problem any time a liquid flows through
a restriction in the piping, volute, or changes direction
suddenly. The fluid will accelerate as it changes direction.
The same acceleration takes place as the fluid flows in the
small area between the tip of the impeller and the volute
cut water.
A noise is heard
- Any time a fluid moves faster than the speed of sound,
in the medium you are pumping, a sonic boom will be heard.
The speed of sound in water is 4800 feet per second (1480
meters/sec) or 3,273 miles per hour (5,267 kilometers per
hour).
Pump parts show damage
- The bubble tries to collapse on its self. This is called
imploding, the opposite of exploding. The bubble is trying
to collapse from all sides, but if the bubble is laying against
a piece of metal such as the impeller or volute it cannot
collapse from that side, so the fluid comes in from the opposite
side at this high velocity proceeded by a shock wave that
can cause all kinds of damage. There is a very characteristic
round shape to the liquid as it bangs against the metal creating
the impression that the metal was hit with a "ball peen hammer".
- This damage would normally occur at right angles to the
metal, but experience shows that the high velocity liquid
seems to come at the metal from a variety of angles. This
can be explained by the fact that dirt particles get stuck
on the surface of the bubble and are held there by the surface
tension of the fluid. Since the dirt particle has weakened
the surface tension of the bubble it becomes the weakest
part and the section where the collapse will probably take
place. The higher the capacity of the pump the more likely
cavitation will occur. Some plants inject air into the suction
of the pump to reduce this capacity and lower the possibility
of cavitation. They choose this solution because they fear
that throttling the discharge of a high temperature application
will heat the fluid in the pump and almost guarantee the
cavitation. In this case air injection is the better choice
of two evils.
High specific speed pumps have a different impeller shape
that allows them to run at high capacity with less power and
less chance of cavitating. You normally find this impeller
in a pipe shaped casing rather than the volute type of casing
that you commonly see.
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