The First Step in Pressure Pulsation Analysis – Examining the Oscillation Modes

Before conducting a comprehensive pressure pulsation analysis, RohrLEx first gains a thorough understanding of the resonance behavior within the piping system. Three key questions are at the forefront:

• What pulsation sources are present?
• What is the topology of the piping system?
• And most importantly – how are the pipe terminations configured?

The type of pipe terminations plays a crucial role, as it significantly influences which vibration modes develop within the system. Depending on the combination of boundary conditions, different resonance patterns emerge, which are essential for analyzing and optimizing the system.

The typical vibration modes can be categorized as follows:

What types of vibrational modes are there?

The modes in a simple hydraulic pipeline can be divided into the two categories of "identical termination" or "opposite termination". In this context, one also refers to the termination impedances of the line. The termination impedances determine whether a so-called λ/4 or a λ/2 vibrational mode is formed. In this context, "identical" means that both line terminations are either "open" (reflection factor of -1) or "closed" (reflection factor of 1) with regard to their wave reflection behavior. In the case of opposite terminations, one pipe end is "open" and the other "closed".

The vibrational mode determines at which point of the pipe system pressure nodes and antinodes are located. Knowledge of the pressure antinode position is important for positioning a damping measure or an attenuator (resonator).

RohrLEx has also published a flyer on vibrational modes in hydraulic networks which presents hydraulic example systems with their respective natural modes and describes how the vibrational mode withinin a cylinder drive changes depending on the stroke.

A pressure-controlled pump that delivers into a pipeline with a closed proportional valve or a hydrostatic transmission (pump - pipeline - motor) are examples for systems that are most likely to resemble a "closed" boundary condition on both sides and thus show a λ/2-waveform.

This corresponds to the application in which a pump fills a reservoir. It also applies to a cylinder that has extended very far. Here, the pump here represents the closed end and the cylinder volume the open end.

The "open-closed" vibration condition often occurs in vehicle hydraulic systems in which the road surface causes vibration excitation on the steering cylinder or air spring. As a result, a flow rate pulsation is then generated in the system, which causes a disturbing pressure pulsation at the valve, if the λ/4 resonance frequency is excited.

The application case "open - open" is given when two pressure reservoirs (e.g. large vessels) are connected by a pipeline. This application is rather rare in hydraulic systems. In practice, however, it may occur if, for example, a pump is used together with an accumulator in a constant pressure system and both components are connected to an extended cylinder via a pipeline.