CE 3372 Water Systems Design Meeting 007 Pumps

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CE 3372 Water Systems Design Meeting 007

CE 3372 Water Systems Design Meeting 007

Pumps • Chapter 2, pp 48 – 64 • Pumping

Pumps • Chapter 2, pp 48 – 64 • Pumping

Pumps • Used to “lift” water from a low elevation to a higher elevation.

Pumps • Used to “lift” water from a low elevation to a higher elevation. • Used to “boost” pressures and/or maintain velocities in a system

Pumps • Two principal types of pumps – Positive Displacement – Centrifugal (Rotating machinery)

Pumps • Two principal types of pumps – Positive Displacement – Centrifugal (Rotating machinery)

Positive Displacement Pumps • Produce lower flow rates than centrifugal-type pumps. • Can produce

Positive Displacement Pumps • Produce lower flow rates than centrifugal-type pumps. • Can produce much higher heads than centrifugal pumps. – Positive displacement pumps are comparatively rare in civil engineering applications, but not entirely absent. – Positive displacement pumps come in two varieties, reciprocating pumps and rotary pumps.

Positive Displacement Pumps • Piston Pump – A piston pump is an example of

Positive Displacement Pumps • Piston Pump – A piston pump is an example of a reciprocating type pump. • The piston moves up and down and the check valves prevent back flow. • On the upstroke (as depicted) the chamber fills with liquid, and on the downstroke the liquid is pushed out the chamber. • The bore diameter, stroke length, and stroke rate are the principal determinants of the operating character of a piston pump. • If no flow can occur (i. e. if the discharge is blocked) the piston pump can and will quickly destroy itself.

Positive Displacement Pumps • Screw Pump – A screw pump is an example of

Positive Displacement Pumps • Screw Pump – A screw pump is an example of a rotating type pump. • The auger flights catch a portion of the water and lift it as the pump screw rotates in the trough. • Alternatively the augers can be built inside a tube and the tube serves as the trough. . • The flight pitch, flight diameter, fill depth, pump angle and angular rotation speed are the principal determinants of pump characteristics. • Screw pumps are commonly used in wastewater lifting and hurricane barrier lifting. • This type of pump is very tolerant of debris in the liquid, and can move large volumes with reasonable energy input. • However, when these pumps fail, they do so quite spectacularly!

Positive Displacement Pumps – Array of Screw pumps that used to lift wastewater into

Positive Displacement Pumps – Array of Screw pumps that used to lift wastewater into the Sims South WWTP in Houston Texas. – At full permitted capacity they could lift about 120 MGD. – The original design had an un-filled bay for a fifth pump, but it was never put into service. – Eventually the pumps were removed and replaced by 6 -20 MGD centrifugal pumps.

Positive Displacement Pumps – Screw pump operation curve Fill Depth (feet) Discharge (gpm)

Positive Displacement Pumps – Screw pump operation curve Fill Depth (feet) Discharge (gpm)

Centrifugal Pumps • Accelerate water using an impeller that adds velocity head proportional to

Centrifugal Pumps • Accelerate water using an impeller that adds velocity head proportional to the angular velocity of the impeller and the impeller diameter. Discharge Suct ion ( Eye)

Centrifugal Pumps • Typical vendor supplied pump curve Operation Curve for Particular Impeller Added

Centrifugal Pumps • Typical vendor supplied pump curve Operation Curve for Particular Impeller Added Head NPSH required Discharge

Axial Flow Pumps • Axial flow pumps have impellers whose axis of rotation is

Axial Flow Pumps • Axial flow pumps have impellers whose axis of rotation is collinear with the discharge (at least close). • Used in high flow, low head applications. discharge suction

Axial Flow Pumps • East Lab Axial Flow Pump (give idea of size) discharge

Axial Flow Pumps • East Lab Axial Flow Pump (give idea of size) discharge suction

Axial Flow Pumps • Typical Operation Curve Added Head Discharge

Axial Flow Pumps • Typical Operation Curve Added Head Discharge

Pump Curve Determination • Typical Experimental Apparatus

Pump Curve Determination • Typical Experimental Apparatus

Pump Curve Determination • The actual characteristics of real pumps are determined experimentally —

Pump Curve Determination • The actual characteristics of real pumps are determined experimentally — usually results are supplied by the pump vendor. – The pump is in the right-most pit in the apparatus, discharge is measured at a weir. – The discharge is throttled to produce the load to generate a pump curve, and the suction side water depth is maintained by recirculation. • Generally the pumps are tested to cavitation to determine the NPSH required for each discharge.

Pump Curve Determination • The results of such tests are reported on charts that

Pump Curve Determination • The results of such tests are reported on charts that as a minimum should supply: – Added head versus discharge. – Wire-to-water efficiency versus discharge. – Mechanical power versus discharge. – Net Positive Suction Head required versus discharge.

Suction Requirements • The most common cause of pumping failure is poor suction conditions.

Suction Requirements • The most common cause of pumping failure is poor suction conditions. • A centrifugal pump cannot lift water unless it is primed, or the first stage impellers are located below the static hydraulic grade line in the suction pit at pump start-up. • Liquid must enter the pump eye under pressure; this pressure is called the Net Positive Suction Head available (NPSHa).

Suction Requirements • The manufacturer supplies a value for the minimum pressure the pump

Suction Requirements • The manufacturer supplies a value for the minimum pressure the pump needs to operate. • This pressure is the Net Positive Suction Head required (NPSHr). • For a system to work: NPSHa> NPSHr over all operating conditions, including startup and shut-down.

Suction Requirements • Available suction is computed from Frictional head loss in inlet piping

Suction Requirements • Available suction is computed from Frictional head loss in inlet piping Absolute pressure at liquid surface in suction pit Static elevation of the liquid above the pump inlet eye Absolute vapor pressure at liquid pumping temperature

Suction Requirements • Illustrative Example

Suction Requirements • Illustrative Example

Suction Requirements • Illustrative Example

Suction Requirements • Illustrative Example

Suction Requirements • Illustrative Example

Suction Requirements • Illustrative Example

Suction Requirements • Illustrative Example

Suction Requirements • Illustrative Example

Suction Requirements • Illustrative Example

Suction Requirements • Illustrative Example

System Curves • A system curve is a plot of required head versus flow

System Curves • A system curve is a plot of required head versus flow rate in a hydraulic system. – The curve depicts how much energy is necessary to maintain a steady flow under the supplied conditions. – The exercises involving energy equation and added pump head, if results are expressed in terms of discharge Q are system curves.

System Curves • Consider the following hydraulic system. – Apply the energy equation and

System Curves • Consider the following hydraulic system. – Apply the energy equation and incorporate various friction components. – Result is a system curve.

System Curves • This relationship tells us that the added head has to be

System Curves • This relationship tells us that the added head has to be at least 30 meters just the keep the reservoirs at the two levels shown, if any flow is to occur the pump must supply at least 30+meters of head.

System Curves • If the curve is plotted with discharge in the horizontal axis,

System Curves • If the curve is plotted with discharge in the horizontal axis, something like the sketch below results.

System Curves • The system curve is used to select an appropriate pump or

System Curves • The system curve is used to select an appropriate pump or set of pumps. Consider the sketch below – Pump A cannot meet the needs of the system at any flow rate while Pump B supplies enough head over part of the system curve. – The shaded area between the Pump B curve and the system curve is the area where the pump supplies excess head.

System Curves • Generally a designer would be prudent to have a throttle valve

System Curves • Generally a designer would be prudent to have a throttle valve in line with the pump that can be used to match performance (throttling the pump moves the system curve up) – throttling wastes energy, but nevertheless is suggested. – The throttle valve also serves as an isolation valve if the pump station needs to be removed from the network for some reason. • The sketch is the kind of pump system suggested by the pumpsystem curve overlay. • While certainly a common configuration, the designer has considerable flexibility if they choose multiple pumps and use valves and/or variable frequency drives (an electronic component that lets the pumps run at different speeds).

System Curves • Series and parallel combinations can be used to adjust “pump curves”

System Curves • Series and parallel combinations can be used to adjust “pump curves” to fit system requirements. Parallel pumps add flow for given head Series pumps add head for given flow

Pumps in EPA-NET • Pumps are modeled as links between two nodes that have

Pumps in EPA-NET • Pumps are modeled as links between two nodes that have pumping curve properties. • Each node must have appropriate elevations. – A pump is added as a link, then the pump curve is specified for that pump. – The program will operate the pump out-of-range but issue warnings to guide the analyst to errors.

Pumps in EPA-NET • Example: – Simulate the single pipeline system depicted below. –

Pumps in EPA-NET • Example: – Simulate the single pipeline system depicted below. – Can the yellow pump curve provide the necessary added head? – How about the red pump curve?

Readings • Chapter 2, pp 48 – 64 • EPA NET User Manual –

Readings • Chapter 2, pp 48 – 64 • EPA NET User Manual – how to model pumps in a pipeline system.

Exercises • Exercise Set #7 • Problem 2. 39, Chin pg 94 – “by

Exercises • Exercise Set #7 • Problem 2. 39, Chin pg 94 – “by hand” • Problem 2. 39, Chin pg 94 – “by EPA-NET”