Modal analysis of a spinning disk in a dense fluid as a model for high head hydraulic turbines

Louyot, Max; Nennemann, Bernd; Monette, Christine; Gosselin, Frédérick P.

doi:10.1016/j.jfluidstructs.2020.102965

Cited by 16 publications

(5 citation statements)

References 40 publications

(57 reference statements)

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“…Louyot proposed an analytical modal analysis method based on an assumed modal approach and potential flow theory and a modal force computational fluid dynamics (CFD) method. Both methods accurately predict intrinsic frequency splitting and intrinsic frequency drift with errors within the experimentally allowed limits [37][38][39][40].…”

Section: Introductionmentioning

confidence: 91%

A Review of the Efficiency Improvement of Hydraulic Turbines in Energy Recovery

Song

Xue

et al. 2023

Processes

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Turbine energy recovery is a process energy saving technology, and understanding turbine efficiency has important operational and economic benefits for the operator of a power plant. There are three main areas of research into turbine energy efficiency: the structural performance of the turbine itself, the configuration of the recovery device and the regulation of operating conditions. This paper summarizes recent research advances in hydraulic turbine energy efficiency improvement, focusing on the design factors that can affect the overall efficiency of a hydraulic turbine. To quantify the impact of these factors, this paper investigates the effects of surface roughness, flow rate, head and impeller speed on overall efficiency. Methods for optimizing improvements based on these design factors are reviewed, and two methods, the Box–Behnken Design method and the NSGA-II genetic algorithm, are described with practical examples to provide ideas for future research.

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Section: Introductionmentioning

confidence: 91%

A Review of the Efficiency Improvement of Hydraulic Turbines in Energy Recovery

Song

Xue

et al. 2023

Processes

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“…In Table 1 some mode shapes of a disk clamped at its center are shown and sorted by the number of nodal diameters (D) and nodal circles (C). As it was studied by many authors [17,26,[28][29][30][31], the vibration mode shapes of a disk have combinations of nodal diameters and nodal circles, which increase their number with the mode order. For convenience, in this work, the mode shapes related to the disk will be called modes "(m, n)" for modes shapes with m nodal diameter and n nodal circles.…”

Section: Modal Characteristics Of a Disk-like Structurementioning

confidence: 99%

“…It was found that while frequencies of the disk decrease when the disk gets close to the rigid wall, the opposite occurs when the disk gets close to the non-rigid wall. Louyot et al [17] made a modal analysis of a spinning disk in a dense fluid as a model for a high-head hydraulic runner. The mode shapes were extracted and, an expression for co-and counter-rotating wave angular frequency was analytically determined.…”

Section: Introductionmentioning

confidence: 99%

Analysis of the Mode Shapes of Kaplan Runners

et al. 2022

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To prevent lifetime shortening and premature failure in turbine runners, it is of paramount importance to analyse and understand its dynamic response and determine the factors that affect it. In this paper, the dynamic response of a Kaplan runner is analysed in air by numerical and experimental methods. First, to start the analysis of Kaplan runner mode shapes, its geometry is simplified and modelled as a bladed disk. Bladed disks with different blade numbers are investigated, by numerical simulation, in order to understand the influence of this parameter on its modal characteristics. Then, mode shapes extracted are characterized and a classification is proposed. Second, an existing Kaplan runner is simulated by Finite Elements Method (FEM) and its mode shapes are extracted. The obtained results are contrasted with the bladed disks mode shapes, in order to validate the classification proposed. The simulated Kaplan runner is also experimentally studied. A numerical modal analysis is carried out in the real runner. Different, global and local, mode shapes are identified. The global mode shapes extracted by numerical and experimental modal analysis are compared and discussed. Finally, the local mode shapes identified are commented and explained by means of numerical simulation.

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“…For instance, the ND vibration modes evolve from standing mode shapes under non-rotating conditions to traveling mode shapes under rotating conditions. Under non-rotating conditions, the displacements of each point of the disk are either in phase or out of phase, while under rotating conditions the displacements are phase-shifted, resulting in a wave traveling over the disk [17,[20][21][22].…”

Section: Introductionmentioning

confidence: 99%

Assessment of Novel Modal Testing Methods for Structures Rotating in Water

2023

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The current paper presents an investigation into novel modal testing methods applied to a disk–shaft structure at different rotating speeds in air and water. The structure was excited using three different methods: an instrumented hammer, a piezoelectric PZT patch glued on the disk and a transient ramp-up. The structural response was measured using an accelerometer and strain gauges mounted on board as well as accelerometers and displacement lasers mounted off board. The potential to excite the natural frequencies using each excitation method and to detect natural frequencies with each sensor was analyzed and compared. Numerical structural and acoustic–structural modal and harmonic analyses of the non-rotating disk in air and water were also performed, taking into consideration the PZT patch. The numerical results showed a close agreement with the experimental ones in both air and water. It was found that the rotating speed of the disk modified the detected natural frequencies, depending on the frame of reference of the sensor. Finally, the PZT patch and the transient ramp-up were proven to be reliable methods to excite the natural frequencies of the current test rig and to be potentially applicable in full-scale hydraulic turbines under operating conditions.

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Modal analysis of a spinning disk in a dense fluid as a model for high head hydraulic turbines

Cited by 16 publications

References 40 publications

A Review of the Efficiency Improvement of Hydraulic Turbines in Energy Recovery

A Review of the Efficiency Improvement of Hydraulic Turbines in Energy Recovery

Analysis of the Mode Shapes of Kaplan Runners

Assessment of Novel Modal Testing Methods for Structures Rotating in Water

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