Npsh – Xylem GLSSV2 SSV Series Vertical Multi-Stage Pumps D1 User Manual

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Technical Data – NPSH

NPSH

The minimum operating values that can be reached at the pump

suction end are limited by the onset of cavitation.
Cavitation is the formation of vapor-filled cavities within liquids

where the pressure is locally reduced to a critical value, or where

the local pressure is equal to, or just below the vapor pressure of

the liquid.
The vapor-filled cavities flow with the current and when they

reach a higher pressure ares the vapor contained in the cavities

condenses. The cavities collide, generating pressure waves that

are transmitted to the walls. These, being subjected to stress

cycles, gradually become deformed and yield due to fatigue. This

phenomenon, characterized by a metallic noise produced by the

hammering on the pipe walls, is called incipient cavitation.
The damage caused by cavitation may be magnified by electro-

chemical corrosion and a local rise in temperature due to the plas-

tic deformation of the walls. The materials that offer the highest

resistance to heat and corrosion are alloy steels, especially austen-

itic steel. The conditions that trigger cavitation may be assessed

by calculating the total net suction head, referred to in technical

literature with the acronym NPSH (Net Positive Suction Head).
The NPSH represents the total energy (expressed in feet) of the

liquid measured at suction under conditions of incipient cavita-

tion, excluding the vapor pressure (expressed in feet) that the

liquid has at the pump inlet.
To find the static height (hz) at which to install the machine under

safe conditions, the following formula must be verified:
h

p

+ h

z

≥ (NPSHr + 2 ft) + h

f

+ h

pv

where:
h

p

is the absolute pressure applied to the free liquid surface in

the suction tank, expressed in feet of liquid; hp is the

quotient between the barometric pressure and the specific

weight of the liquid.

h

z

is the suction lift between the pump axis and the free liquid

surface in the suction tank, expressed in feet; hz is negative

when the liquid level is lower than the pump axis.

h

f

is the flow resistance in the suction line and its accessories,

such as: fittings, foot valve, gate valve, elbows, etc.

h

pv

is the vapor pressure of the liquid at the operating

temperature, expressed in feet of the liquid. hpv is the

quotient between the Pv vapor pressure and the liquid‘s

specific weight.

0.5 is the safety factor.

The maximum possible suction head for installation depends on

the value of the atmospheric pressure (i.e. the elevation above

sea level at which the pump is installed) and the temperature of

the liquid.
To help the user, with reference to water temperature (40ºF) and

to the elevation above sea level, the following tables show the

drop in hydraulic pressure head in relation to the elevation above

sea level, and the suction loss in relation to temperature.

Water Temperature (ºF) 68

104

140

176

194

230

248

Suction Loss (ft)

-.7

2.3

6.6

16.4 24.3 50.5 70.5

Elevation Above Sea Level (ft) 1600 3300 4900 6500 8200 9800
Suction Loss (ft)

1.8

3.6

5.4

7.2

9.0

10.8

To reduce it to a minimum, especially in cases of high suction

head (over 13 – 16 feet) or within the operating limits with high

flow rates, we recommend using a suction line having a larger

diameter than that of the pump’s suction port. It is always a good

idea to position the pump as close as possible to the liquid to be

pumped.