Abstract
Flow-induced vibration is a major issue for spring-loaded valves. However, their complex geometry, combined with their diversity of operational conditions, creates a significant challenge for modelling their dynamic response to potential excitation mechanisms. This paper proposes an analytical framework to describe flow–sound–structurecoupling in spring-loaded valves operating at subcritical conditions, therefore without the occurrence of choking at the vena contracta. The model consists of a single-degree of freedom model of the valve structure, a pseudo-force implicit algorithm to calculate impact forces, a one-dimensional unsteady Bernoulli model to describe the flow, and a one-dimensional wave propagation finite difference scheme to account for the acoustic feedback. The model has shown excellent agreement with experimental results as well as promising predictive capabilities for valve life and wear assessment.
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