Analytical studies were developed on the transient behavior of a cavitating centrifugal pump during the transient operations, including the sudden opening/closure of the discharge valve and the pump startup/shutdown. In order to investigate the mechanism of the low cycle oscillations of both the pressure and the flowrate at a rapid change of the pump system conditions, an unsteady flow analysis was made for the cavitating pump-system by assuming the transient pump performance to be quasi-steady. The calculated unsteady pressure and flowrate during the transient period agree with the corresponding measured time histories. It is shown that the fluctuations of delivery pressure and discharge flowrate at pump rapid startup or sudden valve opening are caused by peculiar oscillating cavitation dynamics inside the pump at rapid increase in flowrate, while the fluctuations at pump rapid shutdown or sudden valve closure are related to the collapse of cavitation bubbles or water column separation in the suction pipe at rapid decrease in flowrate. Moreover, the occurrence of transient fluctuations in pressure and flowrate was predicted by examining the critical condition which creates the occurrence of two different flow mechanisms i.e., (A) oscillating cavitation and (B) water column separation including also the collapse of the cavitation bubbles. These flow mechanisms were represented with two flow models i.e., (A) unsteady cavitating flow incorporating effects of cavitation compliance and mass flow gain factor and expressed by a set of ordinary differential equations solved with the Cardano Method and (B) water-hammer type model including Discrete Free Gas Model and solved with method of characteristics. The calculated critical conditions for the occurrence of the oscillating cavitation and water column separation agree qualitatively with measured ones.

1.
Brennen
C. E.
, and
Acosta
A. J.
,
1973
, “
Theoretical Quasi-Steady Analysis of Cavitation Compliance in Pump
,”
Journal of Spacecraft and Rockets
, Vol.
10
, No.
3
, pp.
175
180
.
2.
Greitzer
E. M.
,
1981
, “
The Stability of Pumping Systems
,”
ASME Journal of Fluids Engineering
, Vol.
103
, pp.
193
242
.
3.
Sack
L. E.
, and
Nottage
H. B.
,
1965
, “
System Oscillations Associated With Cavitating Inducers
,”
ASME Journal of Basic Engineering
, Vol.
87
, pp.
917
924
.
4.
Tanaka, T., and Tsukamoto, H., 1999a, “Transient Behavior of a Cavitating Centrifugal Pump at Rapid Change in Operating Conditions—Part I: Transient Phenomena at Opening/Closure of Discharge Valve,” ASME Journal of Fluids Engineering, published in this issue pp. 841–849.
5.
Tanaka, T., and Tsukamoto, H., 1999b, “Transient Behavior of a Cavitating Centrifugal Pump at Rapid Change in Operating Conditions—Part 2: Transient Phenomena at Pump Startup/Shutdown,” ASME Journal of Fluids Engineering, published in this issue pp. 850–856.
6.
Tsukamoto
H.
,
Matsunaga
S.
,
Yoneda
H.
, and
Hata
S.
,
1986
, “
Transient Characteristics of a Centrifugal Pump During Stopping Period
,”
ASME JOURNAL OF FLUIDS ENGINEERING
, Vol.
108
, No.
4
, pp.
392
399
.
7.
Tsukamoto
H.
, and
Ohashi
H.
,
1982
, “
Transient Characteristics of a Centrifugal Pump During Starting Period
,”
ASME JOURNAL OF FLUIDS ENGINEERING
, Vol.
104
, No.
1
, pp.
6
14
.
8.
Watanabe, T., and Kawata, Y., 1978, “Research on the Oscillation Cavitating Inducer,” Proceedings of 9th IAHR Symposium, Vol. 2, Fort Collins, pp. 265–277.
9.
Wylie
E. B.
,
1984
, “
Simulation of Vaporous and Gaseous Cavitation
,”
ASME JOURNAL OF FLUIDS ENGINEERING
, Vol.
106
, No.
3
, pp.
307
311
.
10.
Wylie, E. B., and Streeter, V. L., 1978, Fluid Transients, McGraw-Hill, New York.
11.
Yamamoto
K.
,
Outa
E.
,
Sano
M.
,
Miwa
T.
, and
Okada
K.
,
1989
, “
Examination of Discrete Cavity Models for Waterhammer Analysis Including Column Separation in a Horizontal Pipeline
,”
Trans. of JSME, Series B
, Vol.
55
, No.
513
, pp.
1296
1301
(in Japanese).
This content is only available via PDF.
You do not currently have access to this content.