Laser Velocimeter Measurements in a Centrifugal Flow Pump

Miner, Steven Merritt; Beaudoin, R. J.; Flack, Ronald D.

doi:10.1115/1.3262257

Cited by 49 publications

(34 citation statements)

References 11 publications

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“…On the contrary, measurements by Miner et al (1989) showed incipient recirculation in the single volute at design flow in the proximity of the tongue, and extensive recirculation for 40% design flow at window 6.…”

Section: Discussionmentioning

confidence: 94%

“…First, the flow was assumed to be uniform over eight equal sized sectors (defined as Distribution 1). Second, experimental investigations, such as those performed by Brownell and Flack (1984) and Miner et al (1989), are indicative of narrower regions of recirculation in the proximity of the tongue. Because the influence of the cutwaters is localized and less than 1/8 of the exit flow area is affected, each of the sectors near the cutwaters were considered to encompass only 1/16 of the area, which is consistent with the observations of Brownell and Flack and Miner et al, while 'the adjacent sectors were considered as 5/32 of the area (Distribution 2).…”

Section: Mass Flow Ratementioning

confidence: 99%

“…20, where slip factor values calculated from data by Miner et al (1989) Busemann (1928) and Wiesner (1967) for this pump geometry are 0.76 and 0.80, respectively. Miner et al (1989) calculated the slip factor for the single volute geometry using an average radial velocity, Cr (averaged circumferentially and axially), in place of Q/2"rrrb. The value of slip factor using this method was within 5% of the value reported in this paper.…”

Section: Slip Factormentioning

confidence: 99%

“…The pump used for this study is documented in Hamkins and Flack (1987), Miner et al (1989) indicated that the flow was swirl free three diameters upstream at shut off conditions. The second flow straightener, 9 pipe diameters upstream of the orifice meter, conditions the flow for the orifice plate.…”

Section: Experimental Apparatus Pump and Flow Loopmentioning

confidence: 99%

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Laser Velocimetry Measurements in a Double Volute Centrifugal Pump

Ojeda

Flack

Miner

1995

International Journal of Rotating Machinery

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Laser velocimetry measurements were taken in a double volute/single discharge centrifugal pump (0.60 specific speed, 1583 US units) with symmetrical volute halves. Blade-to-blade radial and tangential velocity profiles at the impeller exit are presented and compared to data for a similar single volute pump. Flow rates ranged from 40% of design flow to the design point. The blade-to-blade profiles were more uniform than for the single volute pump. Also, the average circumferential variations for the double volute pump were more symmetric than for the single volute pump. For the double volute geometry measurements indicate that radial inward flow (recirculation) was only present for flow rates below 60% of design flow, compared to 80% of design flow for the single volute pump. Velocity data was also used to determine volute losses, slip factor, and momentum contributions to the impeller radial forces. Volute losses were quantified and shown to increase for flow rates below 80% of design flow and were approximately 10% of the developed head at 40% flow. The efficiency in the double volute compared to the single volute shows decreased performance for flows above 55% of design flow, which is attributed to increased boundary layer friction; at low flow rates increased performance is ascribed to better control over the recirculation regions. Slip factors were symmetric around the volute but were lower than for a single volute pump. Finally, momentum contributions to the total impeller radial load were shown to be maximum at the design point, contributing 40% of the force developed by the pressure distribution; the significance diminished at lower flow rates and the contribution was negligible at 40% of the design flow.Key Words: Turbomachinery; Pump; Volute; Impeller; Radial thrust; Laser velocimetry he reliability of centrifugal pumps is often coupled to reducing shaft deflections. Hydraulic forces on a pump impeller cause the shaft to deflect creating excessive metallic contact between it and wearing rings and bearings, and hence induce wear and leakage. Increased deflections yield additional fatigue which have been known to cause shaft failure.This hydraulic force arises from non-symmetries in the flow field due to non-uniformity in both the static pressure and exit velocity distribution around the impeller discharge. Hydraulic forces .are minimum when operating at design conditions although they may increase by several orders of magnitude at off-design flow.Pumps, even though intended to operate at design conditions, invariably function at low flow rates since this range covers start-up and shut-down. Furthermore, operation at low flow rates may represent continuous operation for many machines that are required to yield higher discharge pressures or lower flow rates than originally intended. A number of researchers have exam-

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Section: Discussionmentioning

confidence: 94%

Section: Mass Flow Ratementioning

confidence: 99%

Section: Slip Factormentioning

confidence: 99%

Section: Experimental Apparatus Pump and Flow Loopmentioning

confidence: 99%

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Laser Velocimetry Measurements in a Double Volute Centrifugal Pump

Ojeda

Flack

Miner

1995

International Journal of Rotating Machinery

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“…A number of authors have treated this kind of problem like Miner et al [1] for the case of volute. Liu et al [2], Inoue and Cumpsty [3], and Arndt et al [4] have been concerned with the influence of vaned diffuser.…”

Section: Introductionmentioning

confidence: 99%

Optical PIV and LDV Comparisons of Internal Flow Investigations in SHF Impeller

Wuibaut

Bois

Hajem

et al. 2006

International Journal of Rotating Machinery

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The paper presents a comparison between two sets of experimental results in a centrifugal flow pump. The tested impeller is the so-called SHF impeller for which many experimental data have been continuously produced to built databases for CFD code validations with various levels of approximation. Measurements have been performed using optical techniques: 2D particle image velocimetry (PIV) technique on an air test model and 2D laser doppler velocimetry (LDV) technique on a water model, both for different flow rates. For the present study, results obtained by these optical techniques are compared together in terms of phase averaged velocity and velocity fluctuations inside the impeller flow passage for design flow rate.

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Numerical Calculation of 2d, Unsteady Flow in Centrifugal Pumps: Impeller and Volute Interaction

Croba¹,

Kueny²

1996

Int. J. Numer. Meth. Fluids

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Laser Velocimeter Measurements in a Centrifugal Flow Pump

Cited by 49 publications

References 11 publications

Laser Velocimetry Measurements in a Double Volute Centrifugal Pump

Laser Velocimetry Measurements in a Double Volute Centrifugal Pump

Optical PIV and LDV Comparisons of Internal Flow Investigations in SHF Impeller

Numerical Calculation of 2d, Unsteady Flow in Centrifugal Pumps: Impeller and Volute Interaction

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