[摘要] Fluid-induced rotordynamic forces in pumping machinery are well documented but poorly understood. The present research focuses on the rotordynamics due to fluid flow in annuli, in particular, the discharge-to-suction leakage flow in centrifugal pumps. There are indications that the contribution of the front shroud leakage flow can be of the same order of magnitude as contributions from the nonuniform pressure acting on the impeller discharge. Previous investigations have established some ofthe basic traits of these flows. This work furthers the experimental and computational approach to quantify and predict the shroud contribution to the rotordynamicstability of pumping machinery.Childs' bulk flow model for leakage paths is carefully examined, and convective relations for vorticity and total pressure are deduced. This analysis leads to a newsolution procedure for the bulk flow equations which does not resort to linearization or assumed harmonic forms of the flow variables.Experimental results presented show the contributions of the inlet swirl velocitiesto the rotordynamic forces. Antiswirl devices are evaluated for their effectiveness in reducing instability. Additional tests measuring the pressure distributions and the inlet swirl velocities of the leakage flow confirm some of the predictions by numerical analysis.