Abstract
This paper presents an experimental and numerical modal analysis for an external gear pump considering its mounting on a test rig in a laboratory setting. Most of the previous studies on experimental modal analysis (EMA) of hydraulic pumps focused on the modal frequencies to allow model validation. However, the mode shapes of pump bodies have not extensively been discussed. Furthermore, the nature of the pump components assembly and mounting poses some modeling challenges, such as the uncertain material properties of each component, the behavior of the bolted joints, and some critical modeling boundary conditions related to pump mounting. In this regard, the experimentally obtained vibration modes of a reference pump using the least-square complex exponential (LSCE) method are analyzed with an emphasis on the characteristics of the mode shapes. Then, simple modeling strategies are proposed and validated by performing the analysis from the component level to the full assembly. As a result, the mode shapes are categorized depending on the type of motions that the modes exhibit. It is observed that the pump casing does not show any substantial deformation but is close to the rigid body motion. Moreover, without considerably increasing model complexities, the proposed numerical approach provides reasonable accuracy with average errors in modal frequencies of 6%, as well as good agreement in terms of mode shapes. The vibration reduction strategy is briefly discussed based on the measured mode shapes, and the proposed modeling approaches can be useful to study external gear pumps with minimal model complexities yet allowing reasonable result accuracy.
Highlights
The vibration reduction strategy is briefly discussed based on the measured mode shapes, and the proposed modeling approaches can be useful to study external gear pumps with minimal model complexities yet allowing reasonable result accuracy
Focusing on the case of external gear pumps (EGPs), which is the pump design considered in this study, in the literature it is possible to find several fundamental studies related to the principles of fluid-borne noise generation, as well as designs conceived for so-called “low noise” pumps
This study presents a method for studying the dynamic characteristics of an external gear pump (EGP) considering their actual mounting, following both a numerical and an experimental approach for modal analysis
Summary
Excessive noise emissions of hydraulic pumps are a known drawback of hydraulic control technology, which has limited its application or acceptance in various fields that involve human operators in proximity to a hydraulic system. This technology limitation has motivated the hydraulic fluid power community toward the development of solutions for noise mitigation, such as resonators or silencers. Focusing on the case of external gear pumps (EGPs), which is the pump design considered in this study, in the literature it is possible to find several fundamental studies related to the principles of fluid-borne noise generation, as well as designs conceived for so-called “low noise” pumps. Borghi et al [4] addressed the effects of the timing of the internal connections of the tooth space volumes, which influence the fluid-borne noise
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