Robert X. Perez

Pump Wisdom


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Figure 1.5 are shown with a hub fastening the impeller to the shaft, and each of the first five impellers is shown as a hub‐and‐disc version with an impeller cover. The cover (or “shroud”) identifies the first five as “closed” impellers; recall that Figure 1.3 had depicted a semiopen impeller. Semiopen impellers are designed and fabricated without the cover. Finally, open impellers come with free‐standing vanes welded to or integrally cast into the hub. Since the latter incorporate neither disc nor cover, they are often used in viscous or fibrous paper stock applications.

      To properly function, a semiopen impeller must operate in close proximity to a casing internal surface, which is why axial adjustment features are needed with these impellers. Axial location is a bit less critical with closed impellers. Except on axial flow pumps, fluid exits the impeller in the radial direction. Radial and mixed flow pumps are either single or double suction designs; both will be shown later. Once the impellers are fastened to a shaft, the resulting assembly is called a rotor.

Schematic illustration of general flow classifications of process pump impellers.

      Pump impeller flow classifications and the general meaning of specific speed deserve further discussion. Moving from left to right in Figure 1.5, the various impeller geometries reflect selections that start with high differential pressure capabilities and end with progressively lower differential pressure capabilities. Differential pressure is simply discharge pressure minus suction pressure.

      Impellers toward the right are more efficient than those near the left, and pump designers use the parameter specific speed (N s) to bracket pump hydraulic efficiency attainment and other expected attributes of a particular impeller configurations and size. Please be sure not to confuse a very similar sounding parameter, pump suction specific speed (N ss or N sss), with the specific speed (N s). For now, we are strictly addressing specific speed (N s).

      As an example, observe the customary use, whereby with N and Q – the typical given parameters that define centrifugal process pumps – one determines a pivot point. Next, with pivot point and head H, one can easily determine N s. In Figure 1.5, Ns is somewhere between 500 and 15 000 on the US scale. Whenever we find ourselves in that range, we know such a pump exists, and we can even observe the general impeller shape. Keep in mind that thousands of impeller combinations and geometries exist. Impellers with covers are the most prominent in hydrocarbon processes, and an uneven number of impeller vanes is favored over even numbers of vanes for reasons of vibration suppression.

      Pump specific speed, Figure 1.6, might be of primary interest to pump designers, but average users will also find it useful. On the lower right, the illustration gives the equation for N s; it will be easy to see how N s is related to the shaft speed N (rpm), flow Q (gpm or gallons/minute), and head H (expressed in feet). This mathematical expression also has two strange‐looking exponents in it, but the N s nomogram conveys more than meets the eye and can be quite helpful.

Schematic illustration of pump specific speed nomogram allowing quick estimations. Shown in this illustration is a hypothetical pump application with a flow of 100 gpm operating at 3600 rpm (line 1).

      While there are always fringe applications in terms of size and flow rate, this book deals with centrifugal pumps in process plants. These pumps are related to the generic illustrations of Figures 1.1 and 1.2 and others in this chapter. All would somewhat typically – but by no means exclusively – range from 3 to perhaps 300 hp (2–225 kW).

Schematic illustration of double-flow impellers are used for higher flows and relatively equalized (balanced) axial thrust.

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