Flow-induced noise sources and reduction methods in centrifugal pumps: A literature review

This Review describes the research work conducted by many researchers in the field of hydro-acoustics of centrifugal pumps. This study aims to understand the flow induced noise mechanism, factors affecting it, and available methods to attenuate the same in centrifugal pumps. In general, the noise generated by a pump is interpreted in terms of pressure pulsations and can be represented in the frequency domain as a combination of discrete components and broadband components. In the discrete frequency noise component, the major emphasis is given on blade pass frequency noise and its relation to the rotor-stator interaction in pumps. The intensified rotor-stator interaction results in high pressure pulsations, thus strong flow induced noise. The effect of various geometrical parameters on the rotor-stator interaction and available methods to mitigate it to reduce noise are discussed in detail. Apart from the rotor-stator interaction, the importance of energy loss mechanisms, such as flow recirculation, flow-separation, and jet-wakes occurrence in pumps, which affect the blade pass frequency component, are also discussed. One of the other discrete noise components, the rotating stall mechanism with its physical mechanism, was also explored in detail. Subsequently, two major phenomena of broadband noise components, turbulence and cavitation, are explained. For cavitation, the phenomenon is elaborated in detail as well as various methods explored by the researchers to predict the existence of the cavitation phenomenon using the acoustic spectrum. Conclusions are also drawn for each source by describing the major events. In the end, the possible future scope of work that can be explored is given. Published under an exclusive license by AIP Publishing.

Automated summary

This paper summarizes the work of many researchers in the field of hydro-acoustics of centrifugal pumps, focusing on noise generation mechanisms, influencing factors, and methods to reduce noise. It specifically discusses noise components such as pressure pulsations, blade pass frequency noise, turbulence, and cavitation in centrifugal pumps.