A MULTI-LAYER PERCEPTRON APPROACH FOR INDIRECT MEASUREMENT OF EROSIVE CAVITATION IN HYDRAULIC TURBINES

Abderraouf Benabdesselam; Quang Hung Pham; Martin Gagnon; Antoine Tahan

doi:10.1049/icp.2025.2327

A MULTI-LAYER PERCEPTRON APPROACH FOR INDIRECT MEASUREMENT OF EROSIVE CAVITATION IN HYDRAULIC TURBINES

Abderraouf Benabdesselam
, Quang Hung Pham
, Martin Gagnon
, Antoine Tahan

Research output: Contribution to Book/Report types › Contribution to conference proceedings › peer-review

Abstract

Erosive cavitation generates wear in hydraulic turbines, leading to costly maintenance and extended downtime in hydroelectric power plants. This study introduces an indirect measurement approach to predict the intensity of erosive cavitation and its degradation trajectory in hydraulic turbines, using a Multi-Layer Perceptron (MLP) model that predicts the instantaneous rate of cavitation based on operational parameters while also quantifying predictive uncertainty. Although cavitation may appear difficult to predict and complex, this study demonstrates that it can be effectively modeled and predicted using a relatively simple model like MLP, achieving good performances. By accumulating the predictions, we model the cumulative degradation caused by cavitation over time, enabling more informed maintenance scheduling. Additionally, this study explores transfer learning to extend the predictive capability of a model trained on one turbine to predict the erosive cavitation behavior of another turbine.

Original language	English
Title of host publication	15th Prognostics and System Health Management Conference, PHM 2025
Publisher	Institution of Engineering and Technology
Pages	29-34
Number of pages	6
Volume	2025
Edition	10
ISBN (Electronic)	9781837242634, 9781837243143, 9781837243150, 9781837243167, 9781837243235, 9781837243341, 9781837243358, 9781837246847, 9781837246854, 9781837247004, 9781837247011, 9781837247028, 9781837247035, 9781837247042, 9781837247271
DOIs	https://doi.org/10.1049/icp.2025.2327
Publication status	Published - 2025
Event	15th Prognostics and System Health Management Conference, PHM 2025 - Bruges, Belgium Duration: 2 Jun 2025 → 5 Jun 2025

Conference

Conference	15th Prognostics and System Health Management Conference, PHM 2025
Country/Territory	Belgium
City	Bruges
Period	2/06/25 → 5/06/25

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 7 Affordable and Clean Energy

!!!Keywords

CAVITATION
EROSION
HEALTH MANAGEMENT
INDIRECT MEASUREMENTS
PROGNOSTICS
TURBINE-GENERATOR UNIT

Access to Document

10.1049/icp.2025.2327

Cite this

@inproceedings{c5511556e40b4e2daee177b327bd2817,

title = "A MULTI-LAYER PERCEPTRON APPROACH FOR INDIRECT MEASUREMENT OF EROSIVE CAVITATION IN HYDRAULIC TURBINES",

abstract = "Erosive cavitation generates wear in hydraulic turbines, leading to costly maintenance and extended downtime in hydroelectric power plants. This study introduces an indirect measurement approach to predict the intensity of erosive cavitation and its degradation trajectory in hydraulic turbines, using a Multi-Layer Perceptron (MLP) model that predicts the instantaneous rate of cavitation based on operational parameters while also quantifying predictive uncertainty. Although cavitation may appear difficult to predict and complex, this study demonstrates that it can be effectively modeled and predicted using a relatively simple model like MLP, achieving good performances. By accumulating the predictions, we model the cumulative degradation caused by cavitation over time, enabling more informed maintenance scheduling. Additionally, this study explores transfer learning to extend the predictive capability of a model trained on one turbine to predict the erosive cavitation behavior of another turbine.",

keywords = "CAVITATION, EROSION, HEALTH MANAGEMENT, INDIRECT MEASUREMENTS, PROGNOSTICS, TURBINE-GENERATOR UNIT",

author = "Abderraouf Benabdesselam and Pham, \{Quang Hung\} and Martin Gagnon and Antoine Tahan",

note = "Publisher Copyright: {\textcopyright} The Institution of Engineering \& Technology 2025.; 15th Prognostics and System Health Management Conference, PHM 2025 ; Conference date: 02-06-2025 Through 05-06-2025",

year = "2025",

doi = "10.1049/icp.2025.2327",

language = "English",

volume = "2025",

pages = "29--34",

booktitle = "15th Prognostics and System Health Management Conference, PHM 2025",

publisher = "Institution of Engineering and Technology",

edition = "10",

}

Benabdesselam, A, Pham, QH, Gagnon, M & Tahan, A 2025, A MULTI-LAYER PERCEPTRON APPROACH FOR INDIRECT MEASUREMENT OF EROSIVE CAVITATION IN HYDRAULIC TURBINES. in 15th Prognostics and System Health Management Conference, PHM 2025. 10 edn, vol. 2025, Institution of Engineering and Technology, pp. 29-34, 15th Prognostics and System Health Management Conference, PHM 2025, Bruges, Belgium, 2/06/25. https://doi.org/10.1049/icp.2025.2327

A MULTI-LAYER PERCEPTRON APPROACH FOR INDIRECT MEASUREMENT OF EROSIVE CAVITATION IN HYDRAULIC TURBINES. / Benabdesselam, Abderraouf; Pham, Quang Hung; Gagnon, Martin et al.
15th Prognostics and System Health Management Conference, PHM 2025. Vol. 2025 10. ed. Institution of Engineering and Technology, 2025. p. 29-34.

Research output: Contribution to Book/Report types › Contribution to conference proceedings › peer-review

TY - GEN

T1 - A MULTI-LAYER PERCEPTRON APPROACH FOR INDIRECT MEASUREMENT OF EROSIVE CAVITATION IN HYDRAULIC TURBINES

AU - Benabdesselam, Abderraouf

AU - Pham, Quang Hung

AU - Gagnon, Martin

AU - Tahan, Antoine

N1 - Publisher Copyright: © The Institution of Engineering & Technology 2025.

PY - 2025

Y1 - 2025

N2 - Erosive cavitation generates wear in hydraulic turbines, leading to costly maintenance and extended downtime in hydroelectric power plants. This study introduces an indirect measurement approach to predict the intensity of erosive cavitation and its degradation trajectory in hydraulic turbines, using a Multi-Layer Perceptron (MLP) model that predicts the instantaneous rate of cavitation based on operational parameters while also quantifying predictive uncertainty. Although cavitation may appear difficult to predict and complex, this study demonstrates that it can be effectively modeled and predicted using a relatively simple model like MLP, achieving good performances. By accumulating the predictions, we model the cumulative degradation caused by cavitation over time, enabling more informed maintenance scheduling. Additionally, this study explores transfer learning to extend the predictive capability of a model trained on one turbine to predict the erosive cavitation behavior of another turbine.

AB - Erosive cavitation generates wear in hydraulic turbines, leading to costly maintenance and extended downtime in hydroelectric power plants. This study introduces an indirect measurement approach to predict the intensity of erosive cavitation and its degradation trajectory in hydraulic turbines, using a Multi-Layer Perceptron (MLP) model that predicts the instantaneous rate of cavitation based on operational parameters while also quantifying predictive uncertainty. Although cavitation may appear difficult to predict and complex, this study demonstrates that it can be effectively modeled and predicted using a relatively simple model like MLP, achieving good performances. By accumulating the predictions, we model the cumulative degradation caused by cavitation over time, enabling more informed maintenance scheduling. Additionally, this study explores transfer learning to extend the predictive capability of a model trained on one turbine to predict the erosive cavitation behavior of another turbine.

KW - CAVITATION

KW - EROSION

KW - HEALTH MANAGEMENT

KW - INDIRECT MEASUREMENTS

KW - PROGNOSTICS

KW - TURBINE-GENERATOR UNIT

UR - https://www.scopus.com/pages/publications/105016306261

U2 - 10.1049/icp.2025.2327

DO - 10.1049/icp.2025.2327

M3 - Contribution to conference proceedings

AN - SCOPUS:105016306261

VL - 2025

SP - 29

EP - 34

BT - 15th Prognostics and System Health Management Conference, PHM 2025

PB - Institution of Engineering and Technology

T2 - 15th Prognostics and System Health Management Conference, PHM 2025

Y2 - 2 June 2025 through 5 June 2025

ER -

A MULTI-LAYER PERCEPTRON APPROACH FOR INDIRECT MEASUREMENT OF EROSIVE CAVITATION IN HYDRAULIC TURBINES

Abstract

Conference

UN SDGs

!!!Keywords

Access to Document

Other files and links

Fingerprint

Cite this