Tag Archives: Net Positive Suction Head

Suction Throttling NPSH Test Setup

What You Need to Know About NPSH

Most pump problems are related to net positive suction head (NPSH).
By Terry Henshaw, Pumps & Systems February 2018

Definition of NPSH
The margin of pressure over vapor pressure, at the pump suction nozzle, is net positive suction head (NPSH). NPSH is the difference between suction pressure (stagnation) and vapor pressure. In equation form:

NPSH = Ps – Pvap

NPSH = NPSH available from the system, at the pump inlet, with the pump running
Ps = stagnation suction pressure, at the pump inlet, with the pump running
Pvap = vapor pressure of the pumpage at inlet temperature

Since vapor pressure is always expressed on the absolute scale, suction pressure must also be in absolute terms. In U.S. customary units, both pressures must be in pounds per square inch absolute (psia). Gauge pressure is converted to absolute pressure by adding atmospheric pressure. The above equation provides an answer in units of pressure (psi). This can be converted to units of head (feet) by the following equation:

h = 2.31p/SG

h = head in feet
p = pressure in psi
SG = specific gravity of the liquid

Importance of NPSH
NPSH is a subject of extreme importance in all pumping systems. It has been estimated that 80 percent of all pump problems are due to inadequate suction conditions, and most suction problems are related to NPSH. (Either the system does not provide as much as anticipated, or the pump requires more than anticipated.) It is therefore probable that most pump problems are NPSH problems.

Units of NPSH
For centrifugal pumps, NPSH values are expressed in units of specific energy (equivalent column height) such as feet or meters. For displacement pumps (rotary and reciprocating), NPSH values are normally expressed in pressure units such as pounds per square inch (psi), kilopascals pr bars.

NPSH values are neither gauge pressures nor absolute pressures. The “g” in psig means that the pressure is measured above atmospheric pressure. The “a” in psia means that the pressure is measured above absolute zero, a perfect vacuum. NPSH is a measurement of pressure above vapor pressure, so the units of NPSH (in the U.S.) are just psi or feet.

NPSH Available: A System Characteristic
NPSHa stands for NPSH available from the system. It can be calculated by measuring suction pressure at the pump suction nozzle, correcting to datum, adding atmospheric pressure, adding velocity head and subtracting vapor pressure. In equation form:

NPSH = Psg + Pz + Patm + Pvel – Pvap

NPSHa = NPSH available to the pump, psi
Psg = gauge pressure measured at suction nozzle, psig
Pz = elevation of gauge above pump centerline, converted to pressure unites, psi
Patm = atmospheric pressure, psia
Pvel = velocity head, converted to pressure united, psi
Pvap = vapor pressure of the pumpage, at the pump suction nozzle, psia

If desired, all units can be converted to head (feet) prior to plugging into the equation. If the system has not been built, it is necessary to calculate the NPSHa by starting with the pressure in the suction tank. Add atmospheric pressure, add (or subtract) the liquid level above (below) datum, subtract all losses from the tank to the pump and subtract vapor pressure.

NPSH Required: A Pump Characteristic
The letters NPSHr stand for the NPSH required by the pump. This characteristic must be determined by test.
For proper operation of the pump, it is necessary that NPSHa > NPSHr. The system must provide more NPSH than the pump requires.

What Happens When NPSHr Exceeds NPSHa?
One potential complication when NPSHr exceeds NPSHa is cavitation. If at any time the static pressure on a liquid drops below vapor pressure, a portion of the liquid will boil-it will flash to a gas. This formation of gas bubbles is called cavitation. (Cavities form in the liquid.) Such gas formation in a suction pipe or inside a pump may cause a reduction in pump capacity and/or head. It may also cause damage to the pump. As liquid flows into any pump, there is a reduction in pressure. In a centrifugal pump, the liquid accelerates into the eye of the impeller, causing a reduction in pressure. The impeller vanes then slice into the liquid, creating zones of lower pressure.

If a sufficient pressure margin, over vapor pressure, is not provided at the pump inlet, some of the liquid will flash at the leading edge of each vane.

With displacement pumps, the situation is similar. Because the pressure drops as the pumpage moves into the pumping chamber, suction pressure must exceed vapor pressure by some margin to prevent cavitation.

Even though the liquid is cavitating, we usually say that the pump is cavitation. Possible effects of pump cavitation include noise, head and/or capacity loss, and equipment damage. It is not the formation of the bubbles that causes damage. Damage is caused to pump parts when the bubbles collapse or “implode.” When the bubbles collapse on a hard surface, they create a high pressure.

To Quieten a Cavitating CentrifugaI Pump
If a centrifugal pump sounds as if it is pumping gravel, if the system can tolerate it and if no other solution is readily available, inject about ½ percent (by volume) air (or other gas) just upstream (into the inlet) of the pump. Experiment to see how little air is necessary to obtain quiet operation. (Do not try this with a reciprocating pump!)

NPSHr & Suction Specific Speed
Suction specific speed, like specific speed, is not a speed at all. It is an index number, or “yardstick.” It is based on the NPSHr of a centrifugal pump, normally the 3 percent head drop NPSHr and normally at its best efficiency point (BEP). The equation for suction specific speed is the same as specific speed, except that NPSHr is substituted or head, as follows:

S = N√Q/NPSHr0.75

Where (in U.S. units):
S = suction specific speed
N = RPM of pump
Q = pump capacity*†, GPM
NPSHr = NPSH required by pump†, feet

*If the impeller is double suction, Q in the above equation is one-half the BEP capacity of the pump. This is a major difference from calculating specific speed, in which w use total pump capacity, whether the impeller is single suction or double suction.
†Normally calculated at the BEP

The symbol Nss is often used in place of S for suction specific speed. The value of S for most pumps is typically between 7,000 and 15,000. The higher values are more common in higher speed, higher capacity units.

Suction Specific Speed
For a number of years, the push from users and competitors required pump manufacturers to continually strive for lower values of NPSHr. The philosophy was that “The lower the NPSHr, the better the pump.” NPSHr in centrifugal pumps is normally reduced by increasing the diameter of the impeller eye. That philosophy has now changed.

Due to problems that have been attributed to oversized impeller eyes, pump users have established maximum values for S, which establishes minimum values for NPSHr. (See Pumps & Systems, December 2011, pumpsandsystems.com/ analyzing-impeller-eye).

Every centrifugal pump would like to run at its BEP. Pump components would experience maximum life at that capacity. Seldom does a pump run at its BEP, but component life will be significantly extended if it operates within its “stable” window of capacities. Suction specific speed can indicate the size of that window. Pumps with lower values of S have larger windows.

If it is necessary to increase a system’s NPSHa, one or more of the following steps may be employed:

  1. Raise the level of the liquid in the suction vessel.
  2. Cool the liquid (after it leaves the vessel).
  3. Reduce the losses in the suction line by reducing its length, increasing its diameter, reducing number of fittings, etc.
  4. Install a booster pump.
  5. With a reciprocating pump or pulsating rotary pump, install a bottle or suction stabilizer in the suction line adjacent to the pump.

Ways to Reduce NPSHr
If the pump is in the selection stage, one or more of the following options may be employed to reduce the NPSHr:

  1. Use a double-suction impeller.
  2. Use a larger pump.
  3. Use a lower speed pump.
  4. Use an inducer (a small axial-flow impeller built into the eye of the main impeller).
  5. Install the pump at a lower elevation.
  6. With a vertical turbine pump, lower the first-stage impeller (make the pump longer).

All of the above will normally increase the initial cost of the pump and/or installation. Options two and three will also likely result in higher operating cost due to lower efficiency. Option two may result in a pump operating in the hydraulically unstable range. If the pump is already installed, one or more of the following options may be employed to reduce the NPSHr:

  1. If operating near or beyond the SEP, reduce pump capacity.
  2. If operating near shut-off, increase pump capacity (with a bypass if necessary).
  3. Reduce wear ring clearances.
  4. Reduce seal flush flow.
  5. Vent the seal chamber (stuffing box) back to the suction vessel.
  6. On a horizontal multistage pump with a balancing drum, pipe balancing line back to the suction vessel. The valves in this line must be locked open.
  7. On a vertical multistage pump, pipe the bleed-off line from the throat bushing back to the suction vessel. The valves in this line should be locked open.

This article was originally printed in Pumps & Systems magazine February 2018.

Industry News from the Pumps & Systems


The Cost of a Misbehaving Pump

Pump Training & Education

A Complete Line of Pumps for Industry

Vertiflo Pump Company’s Vertical Sump Centrifugal Pumps, Horizontal End Suction Centrifugal Pumps and self-priming pumps are delivered fast, usually in half the typical lead time. Vertiflo’s vertical sump pump line offers up to 3000 GPM, 250′ Heads and 26′ depth. The horizontal end suction pump line offers up to 3000 GPM and 300’ Heads.

Vertiflo pumps are designed for nonresidential applications and currently over 20,000 are operating successfully worldwide. Vertiflo is recognized as a quality manufacturer of dependable pumps, and continues to grow and encompass new applications in the pump industry.