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Main Authors: Bürgler, Matthias, Valero, Daniel, Hohermuth, Benjamin, Boes, Robert M., Vetsch, David F.
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2403.16091
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author Bürgler, Matthias
Valero, Daniel
Hohermuth, Benjamin
Boes, Robert M.
Vetsch, David F.
author_facet Bürgler, Matthias
Valero, Daniel
Hohermuth, Benjamin
Boes, Robert M.
Vetsch, David F.
contents The analysis of bubbly two-phase flows is challenging due to their turbulent nature and the need for intrusive phase-detection probes. However, accurately characterizing these flows is crucial for safely designing critical infrastructure such as dams and their appurtenant structures. The combination of dual-tip intrusive phase-detection probes with advanced signal processing algorithms enables the assessment of pseudo-instantaneous 1-D velocity time series; for which the limitations are not fully fathomed. In this investigation, we theoretically define four major sources of error, which we quantify using synthetically generated turbulent time series, coupled with the simulated response of a phase detection probe. Our findings show that typical high-velocity flows in hydraulic structures hold up to 15% error in the mean velocity estimations and up to 35% error in the turbulence intensity estimations for the most critical conditions, typically occurring in the proximity of the wall. Based on thousands of simulations, our study provides a novel data-driven tool for the estimation of these baseline errors (bias and uncertainties) in real-word phase-detection probe measurements.
format Preprint
id arxiv_https___arxiv_org_abs_2403_16091
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Uncertainties in Measurements of Bubbly Flows Using Phase-Detection Probes
Bürgler, Matthias
Valero, Daniel
Hohermuth, Benjamin
Boes, Robert M.
Vetsch, David F.
Fluid Dynamics
The analysis of bubbly two-phase flows is challenging due to their turbulent nature and the need for intrusive phase-detection probes. However, accurately characterizing these flows is crucial for safely designing critical infrastructure such as dams and their appurtenant structures. The combination of dual-tip intrusive phase-detection probes with advanced signal processing algorithms enables the assessment of pseudo-instantaneous 1-D velocity time series; for which the limitations are not fully fathomed. In this investigation, we theoretically define four major sources of error, which we quantify using synthetically generated turbulent time series, coupled with the simulated response of a phase detection probe. Our findings show that typical high-velocity flows in hydraulic structures hold up to 15% error in the mean velocity estimations and up to 35% error in the turbulence intensity estimations for the most critical conditions, typically occurring in the proximity of the wall. Based on thousands of simulations, our study provides a novel data-driven tool for the estimation of these baseline errors (bias and uncertainties) in real-word phase-detection probe measurements.
title Uncertainties in Measurements of Bubbly Flows Using Phase-Detection Probes
topic Fluid Dynamics
url https://arxiv.org/abs/2403.16091