Pumps are in general classified as Centrifugal Pumps (or Roto-dynamic pumps) and Positive Displacement Pumps.
Centrifugal Pumps (Roto-dynamic pumps)
The centrifugal or roto-dynamic pump produce a head and a flow by increasing the velocity of the liquid through the machine with the help of a rotating vane impeller. Centrifugal pumps include radial, axial and mixed flow units.
Centrifugal pumps can further be classified as
* end suction pumps
* in-line pumps
* double suction pumps
* vertical multistage pumps
* horizontal multistage pumps
* submersible pumps
* self-priming pumps
* axial-flow pumps
* regenerative pumps
Positive Displacement Pumps
The positive displacement pump operates by alternating of filling a cavity and then displacing a given volume of liquid. The positive displacement pump delivers a constant volume of liquid for each cycle against varying discharge pressure or head.
The positive displacement pump can be classified as:
* Reciprocating pumps - piston, plunger and diaphragm
* Power pumps
* Steam pumps
* Rotary pumps - gear, lobe, screw, vane, regenerative (peripheral) and progressive cavity
Selecting between Centrifugal or Positive Displacement Pumps
Selecting between a Centrifugal Pump or a Positive Displacement Pump is not always straight forward.
Flow Rate and Pressure Head
The two types of pumps behave very differently regarding pressure head and flow rate:
* The Centrifugal Pump has varying flow depending on the system pressure or head
* The Positive Displacement Pump has more or less a constant flow regardless of the system pressure or head. Positive Displacement pumps generally gives more pressure than Centrifugal Pump's.
Capacity and Viscosity
Another major difference between the pump types is the effect of viscosity on the capacity:
* In the Centrifugal Pump the flow is reduced when the viscosity is increased
* In the Positive Displacement Pump the flow is increased when viscosity is increased
Liquids with high viscosity fills the clearances of a Positive Displacement Pump causing a higher volumetric efficiency and a Positive Displacement Pump is better suited for high viscosity applications. A Centrifugal Pump becomes very inefficient at even modest viscosity.
Mechanical Efficiency
The pumps behaves different considering mechanical efficiency as well.
* Changing the system pressure or head has little or no effect on the flow rate in the Positive Displacement Pump
* Changing the system pressure or head has a dramatic effect on the flow rate in the Centrifugal Pump
Net Positive Suction Head - NPSH
Another consideration is the Net Positive Suction Head NPSH.
* In a Centrifugal Pump, NPSH varies as a function of flow determined by pressure
* In a Positive Displacement Pump, NPSH varies as a function of flow determined by speed. Reducing the speed of the Positive Displacement Pump pump, reduces the NPSH
Centrifugal Pumps (Roto-dynamic pumps)
The centrifugal or roto-dynamic pump produce a head and a flow by increasing the velocity of the liquid through the machine with the help of a rotating vane impeller. Centrifugal pumps include radial, axial and mixed flow units.
Centrifugal pumps can further be classified as
* end suction pumps
* in-line pumps
* double suction pumps
* vertical multistage pumps
* horizontal multistage pumps
* submersible pumps
* self-priming pumps
* axial-flow pumps
* regenerative pumps
Positive Displacement Pumps
The positive displacement pump operates by alternating of filling a cavity and then displacing a given volume of liquid. The positive displacement pump delivers a constant volume of liquid for each cycle against varying discharge pressure or head.
The positive displacement pump can be classified as:
* Reciprocating pumps - piston, plunger and diaphragm
* Power pumps
* Steam pumps
* Rotary pumps - gear, lobe, screw, vane, regenerative (peripheral) and progressive cavity
Selecting between Centrifugal or Positive Displacement Pumps
Selecting between a Centrifugal Pump or a Positive Displacement Pump is not always straight forward.
Flow Rate and Pressure Head
The two types of pumps behave very differently regarding pressure head and flow rate:
* The Centrifugal Pump has varying flow depending on the system pressure or head
* The Positive Displacement Pump has more or less a constant flow regardless of the system pressure or head. Positive Displacement pumps generally gives more pressure than Centrifugal Pump's.
Capacity and Viscosity
Another major difference between the pump types is the effect of viscosity on the capacity:
* In the Centrifugal Pump the flow is reduced when the viscosity is increased
* In the Positive Displacement Pump the flow is increased when viscosity is increased
Liquids with high viscosity fills the clearances of a Positive Displacement Pump causing a higher volumetric efficiency and a Positive Displacement Pump is better suited for high viscosity applications. A Centrifugal Pump becomes very inefficient at even modest viscosity.
Mechanical Efficiency
The pumps behaves different considering mechanical efficiency as well.
* Changing the system pressure or head has little or no effect on the flow rate in the Positive Displacement Pump
* Changing the system pressure or head has a dramatic effect on the flow rate in the Centrifugal Pump
Net Positive Suction Head - NPSH
Another consideration is the Net Positive Suction Head NPSH.
* In a Centrifugal Pump, NPSH varies as a function of flow determined by pressure
* In a Positive Displacement Pump, NPSH varies as a function of flow determined by speed. Reducing the speed of the Positive Displacement Pump pump, reduces the NPSH
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