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Experiments in Fluids
Published in: Experiments in Fluids 9/2023

01-09-2023 | Research Article

Double-pass imaging background-oriented schlieren technique for focusing on measurement target

Authors: Y. Hirose, M. Yamagishi, S. Udagawa, T. Inage, Y. Tagawa, M. Ota

Published in: Experiments in Fluids | Issue 9/2023

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Abstract

This paper introduces the double-pass imaging background-oriented schlieren (DPBOS) technique to overcome a defocusing problem of conventional background-oriented schlieren (BOS) systems. In the conventional BOS system, a camera focuses on a background situated behind a measurement target, which inevitably causes a blurred image of the target. The advantage of the proposed technique, using a digital projector with proper optical alignment, is that the camera focuses on both the target and the background image at the same time. Therefore, measurement in the vicinity of the target can be achieved with higher sensitivity than that of the conventional BOS system. For validation, a test target (lens) and the density field near a heat sink are measured using the DPBOS. The results show good agreement with theoretical prediction and exhibit higher sensitivity than the conventional and telecentric BOS system. In addition, the accuracy of DPBOS was assessed by comparing the calculated surface temperatures from the displacement of DPBOS and conventional BOS with the corresponding theoretical temperature. As the results, the DPBOS and conventional BOS have errors of 3% and 9%, respectively. The proposed method clearly shows the advantage of DPBOS over BOS in overcoming the defocus problem and achieving high-accuracy measurements.
previous article Experimental study on internal flow structure and dynamics of dense liquid-particle flow down inclined channel
next article Digital holographic microscopy for measurement of instantaneous contact angle of an evaporating droplet

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Metadata
Title
Double-pass imaging background-oriented schlieren technique for focusing on measurement target
Authors
Y. Hirose
M. Yamagishi
S. Udagawa
T. Inage
Y. Tagawa
M. Ota
Publication date
01-09-2023
Publisher
Springer Berlin Heidelberg
Published in
Experiments in Fluids / Issue 9/2023
Print ISSN: 0723-4864
Electronic ISSN: 1432-1114
DOI
https://doi.org/10.1007/s00348-023-03694-9

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