The heat transfer mechanism of a swirling impinging jet in the stagnation region

Atsushi Nozaki; Yasumitsu Igarashi; Koichi Hishida

doi:10.1299/kikaib.68.2300

The heat transfer mechanism of a swirling impinging jet in the stagnation region

Atsushi Nozaki, Yasumitsu Igarashi, Koichi Hishida

システムデザイン工学科

研究成果: Article › 査読

2 被引用数 (Scopus)

抄録

Heat transfer mechanism of a swirling impinging jet in the stagnation region has been experimentally examined, using a combined technique of particle image velocimetry (PIV) and laser induced fluorescence (LIF) for the simultaneous measurements of velocity and temperature fields. The present study indicated that the radial width of the jet was stretched with increasing swirl number Sw, and that this stretching phenomena contributes to radially the maximum local heat transfer coefficient. At the stagnation region, the flow near the heated surface was mixed intermittently by reverse flows toward upstream, and spatial distributions of temperature were well correlated with instantaneous velocity vector maps. The dynamic behavior of recirculation zones, which were attributed to swirl number Sw and impinging distance, mainly determined the turbulent heat transfer at the stagnation region.

本文言語	English
ページ（範囲）	2300-2305
ページ数	6
ジャーナル	Nippon Kikai Gakkai Ronbunshu, B Hen/Transactions of the Japan Society of Mechanical Engineers, Part B
巻	68
号	672
DOI	https://doi.org/10.1299/kikaib.68.2300
出版ステータス	Published - 2002 8

ASJC Scopus subject areas

Condensed Matter Physics
Mechanical Engineering

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10.1299/kikaib.68.2300

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引用スタイル

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abstract = "Heat transfer mechanism of a swirling impinging jet in the stagnation region has been experimentally examined, using a combined technique of particle image velocimetry (PIV) and laser induced fluorescence (LIF) for the simultaneous measurements of velocity and temperature fields. The present study indicated that the radial width of the jet was stretched with increasing swirl number Sw, and that this stretching phenomena contributes to radially the maximum local heat transfer coefficient. At the stagnation region, the flow near the heated surface was mixed intermittently by reverse flows toward upstream, and spatial distributions of temperature were well correlated with instantaneous velocity vector maps. The dynamic behavior of recirculation zones, which were attributed to swirl number Sw and impinging distance, mainly determined the turbulent heat transfer at the stagnation region.",

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