The Effect of Inlet Swirl on the Rotordynamic Shroud Forces in a Centrifugal Pump

Guinzburg, Adiel; Brennen, Christopher E.; Acosta, A. J.; Caughey, T. K.

doi:10.1115/1.2906707

Cited by 19 publications

(15 citation statements)

References 5 publications

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“…6. It is noteworthy that the effect of the leakage flow on the fluid force moment on the precessing back-shroud is the same as that of the inlet swirl on the fluid force on the whirling shroud (Childs [1989] and Guinzburg et al [1993]).…”

Section: Measurements Of the Flow Inmentioning

confidence: 94%

“…Moreover, rotordynamic fluid forces on an impeller shroud with a small shroud/casing clearance are destabilizing (Ohashi et al [1988] and Adkin et al I1988]). For the shroud forces of a whirling centrifugal impeller, numerical (Childs [1989] and Baskharone et al [1994]) and experimental (Guinzburg et al [1993]) investiga-tions have been carried out to see the effect of leakage flow in the shroud/casing clearance and inlet swirl at the entrance of the clearance. It was found that the fluid forces on the shroud become more rotordynamically destabilizing with increasing the inlet swirl at the impeller outer radius.…”

Section: Introductionmentioning

confidence: 99%

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Measurements of the Flow in Backshroud/CasingClearance of Precessing Centrifugal Impeller

Yoshida

Tsujimoto

Ohashi

et al. 1997

International Journal of Rotating Machinery

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Detailed flow measurements have been made to clarify the unsteady flow in the backshroud/ casing clearance of a precessing centrifugal impeller. The unsteady pressure was integrated to obtain the fluid force moment on the precessing impeller shroud for various precessing frequencies. It was shown that the fluid force moment can become rotordynamically destabilizing for small forward precessing motion as originally found by Ohashi et al. The effects of leakage flow in the backshroud/casing clearance and a gap between impeller side plate and casing at the impeller outlet are clearly shown, and the discussions are also made based on the unsteady velocity and pressure measurements.

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Section: Measurements Of the Flow Inmentioning

confidence: 94%

Section: Introductionmentioning

confidence: 99%

Measurements of the Flow in Backshroud/CasingClearance of Precessing Centrifugal Impeller

Yoshida

Tsujimoto

Ohashi

et al. 1997

International Journal of Rotating Machinery

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“…Though some early data on the rotordynamic forces in a centrifugal pump were obtained by Shoji and Ohashi [8], the Caltech program added greatly to the data base. Data were obtained for many different types of impellers (centrifugal and axial, shrouded and unshrouded, with and without cavitation), for many different types of volutes and for parametric variations of the forces with pump operating point, pump cavitation and various clearances and other factors [6,7,[9][10][11][12][13][14][15][16][17][18][19]. Typical data for the dimensionless normal and tangential forces, F n and F t ; as a function of the frequency ratio, o=O; are presented in Figure 3 for a conventional centrifugal pump impeller operating in a single vaneless volute.…”

Section: Measurements In Centrifugal Pumpsmentioning

confidence: 99%

“…Guinzburg et al [13,14,29], Uy and Brennen [16,17] and Hsu and Brennen [18] also conducted experimental investigations of the effect on the rotordynamic forces of the inlet swirl to the leakage flow path. This was accomplished by installing guide vanes at the leakage inlet to introduce pre-rotation in the direction of shaft rotation.…”

Section: Effects Of Inlet Swirlmentioning

confidence: 99%

“…Figure 9 shows a typical installation designed for a swirl angle of 68 other vanes with angles of 18 and 28 were also fabricated. With this installation and assuming that the flow is parallel with the vanes, the swirl ratio, G (defined as the circumferential fluid velocity divided by the radial fluid velocity), depends on the flow coefficient and turning angle, a; according to G=j ¼ H=B tan a where B ¼ 0:318 cm is the width of the channel containing the vanes [13]. Some of the early data and analysis assumed, not unreasonably, that the flow angle would be equal to the vane angle; later this was found to be a serious source of error and the correct effect of inlet swirl was finally established by Hsu and Brennen [18] by direct measurement of the fluid swirl velocity and flow angle at inlet.…”

Section: Effects Of Inlet Swirlmentioning

confidence: 99%

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Fluid-induced rotordynamic forces and instabilities

Brennen

Acosta

2006

Struct. Control Health Monit.

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SUMMARYIn the late 1970s, the authors began a collaboration with our colleague Tom Caughey that helped define a new set of fluid-structure interaction phenomena in turbomachines, namely fluid-induced rotordynamic forces and instabilities. That collaboration and the 31 joint "ABC" papers it produced epitomized Tom Caughey's genius and we reprise it here in his honor.The design of the Space Shuttle Main Engine (SSME) pushed beyond the boundaries of many known technologies. In particular, the rotating speeds and operating conditions of the high speed liquid oxygen and liquid hydrogen turbopumps were extreme and early testing revealed a whirl instability whose magnitude exceeded expectations and allowable limits. It was suspected and later proven that fluid-induced rotordynamic effects were a contributing factor and yet very little was known of such phenomena. As one of the efforts seeking understanding, we constructed a facility to measure fluid-induced rotordynamic forces. This was subsequently used in a broad range of investigations. Initially, the effort was directed to understanding the source and parametric variations of destabilizing fluid forces. Later various components of the flow in a high speed turbopump were investigated. And finally, some ameliorative measures and their effectiveness were examined. This paper reviews this body of knowledge and the lessons learnt along the way.

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Rotordynamics of Impeller Eye Seals with Wear-Damaged Teeth in Centrifugal Compressors

Rhode

2006

Tribology Transactions

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The Effect of Inlet Swirl on the Rotordynamic Shroud Forces in a Centrifugal Pump

Cited by 19 publications

References 5 publications

Measurements of the Flow in Backshroud/CasingClearance of Precessing Centrifugal Impeller

Measurements of the Flow in Backshroud/CasingClearance of Precessing Centrifugal Impeller

Fluid-induced rotordynamic forces and instabilities

Rotordynamics of Impeller Eye Seals with Wear-Damaged Teeth in Centrifugal Compressors

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