THERMAL ANALYSIS AND OPTIMIZATION OF HIGH-POWER BEAM DEPOSITION TARGET COOLING HEAT SINK FOR ACCELERATOR RADIOISOTOPES APPLICATION

Chengzhan Li; Tao Wang; Cong Guo; Yuyan Jiang; Sicong Tan; Chaohong Guo

doi:10.1615/HeatTransRes.2021039863

THERMAL ANALYSIS AND OPTIMIZATION OF HIGH-POWER BEAM DEPOSITION TARGET COOLING HEAT SINK FOR ACCELERATOR RADIOISOTOPES APPLICATION

Chengzhan Li, Tao Wang^*, Cong Guo^*, Yuyan Jiang, Sicong Tan, Chaohong Guo

^*此作品的通讯作者

科研成果: 期刊稿件 › 文章 › 同行评审

1 引用（Scopus）

摘要

This paper studies thermal performance of hybrid slot jet/minichannel heat sink for radioisotope preparation application using a 3D numerical model. The influence of geometry dimensions (channel shape, channel bottom structure, channel number, and channel length) is discussed. Results indicate that the local convection thermal resistance of hybrid module is gradually increasing along with flow direction; strong vortices are generated in the impingement region and further extend in the channel region; the presence of channel walls in the impingement region contributes to improvement of cooling performance. Compared with rectangular channels, in trapezoidal channels vortices away from the heated surface result in the enhancement of overall thermal resistance. The convex bottom surface possesses a higher overall thermal resistance due to the elevation of thermal-conduction resistance. Finally, for the high-power (∼ 3000 W), ultra-high heat flux (average ∼ 1000 W/cm2) conditions, flat bottom surface, rectangular-shape, 40-mm-long channel, 7-channel hybrid module is chosen to dissipate heat.

源语言	英语
页（从-至）	39-56
页数	18
期刊	Heat Transfer Research
卷	52
期	18
DOI	https://doi.org/10.1615/HeatTransRes.2021039863
出版状态	已出版 - 2021
已对外发布	是

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Li, C., Wang, T., Guo, C., Jiang, Y., Tan, S., & Guo, C. (2021). THERMAL ANALYSIS AND OPTIMIZATION OF HIGH-POWER BEAM DEPOSITION TARGET COOLING HEAT SINK FOR ACCELERATOR RADIOISOTOPES APPLICATION. Heat Transfer Research, 52(18), 39-56. https://doi.org/10.1615/HeatTransRes.2021039863

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title = "THERMAL ANALYSIS AND OPTIMIZATION OF HIGH-POWER BEAM DEPOSITION TARGET COOLING HEAT SINK FOR ACCELERATOR RADIOISOTOPES APPLICATION",

abstract = "This paper studies thermal performance of hybrid slot jet/minichannel heat sink for radioisotope preparation application using a 3D numerical model. The influence of geometry dimensions (channel shape, channel bottom structure, channel number, and channel length) is discussed. Results indicate that the local convection thermal resistance of hybrid module is gradually increasing along with flow direction; strong vortices are generated in the impingement region and further extend in the channel region; the presence of channel walls in the impingement region contributes to improvement of cooling performance. Compared with rectangular channels, in trapezoidal channels vortices away from the heated surface result in the enhancement of overall thermal resistance. The convex bottom surface possesses a higher overall thermal resistance due to the elevation of thermal-conduction resistance. Finally, for the high-power (∼ 3000 W), ultra-high heat flux (average ∼ 1000 W/cm2) conditions, flat bottom surface, rectangular-shape, 40-mm-long channel, 7-channel hybrid module is chosen to dissipate heat.",

keywords = "Gaussian form heat flux, geometry parametric effect, slot jet/minichannel hybrid heat sink, thermal resistance",

author = "Chengzhan Li and Tao Wang and Cong Guo and Yuyan Jiang and Sicong Tan and Chaohong Guo",

year = "2021",

doi = "10.1615/HeatTransRes.2021039863",

language = "English",

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pages = "39--56",

journal = "Heat Transfer Research",

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AU - Li, Chengzhan

AU - Wang, Tao

AU - Guo, Cong

AU - Jiang, Yuyan

AU - Tan, Sicong

AU - Guo, Chaohong

PY - 2021

Y1 - 2021

N2 - This paper studies thermal performance of hybrid slot jet/minichannel heat sink for radioisotope preparation application using a 3D numerical model. The influence of geometry dimensions (channel shape, channel bottom structure, channel number, and channel length) is discussed. Results indicate that the local convection thermal resistance of hybrid module is gradually increasing along with flow direction; strong vortices are generated in the impingement region and further extend in the channel region; the presence of channel walls in the impingement region contributes to improvement of cooling performance. Compared with rectangular channels, in trapezoidal channels vortices away from the heated surface result in the enhancement of overall thermal resistance. The convex bottom surface possesses a higher overall thermal resistance due to the elevation of thermal-conduction resistance. Finally, for the high-power (∼ 3000 W), ultra-high heat flux (average ∼ 1000 W/cm2) conditions, flat bottom surface, rectangular-shape, 40-mm-long channel, 7-channel hybrid module is chosen to dissipate heat.

AB - This paper studies thermal performance of hybrid slot jet/minichannel heat sink for radioisotope preparation application using a 3D numerical model. The influence of geometry dimensions (channel shape, channel bottom structure, channel number, and channel length) is discussed. Results indicate that the local convection thermal resistance of hybrid module is gradually increasing along with flow direction; strong vortices are generated in the impingement region and further extend in the channel region; the presence of channel walls in the impingement region contributes to improvement of cooling performance. Compared with rectangular channels, in trapezoidal channels vortices away from the heated surface result in the enhancement of overall thermal resistance. The convex bottom surface possesses a higher overall thermal resistance due to the elevation of thermal-conduction resistance. Finally, for the high-power (∼ 3000 W), ultra-high heat flux (average ∼ 1000 W/cm2) conditions, flat bottom surface, rectangular-shape, 40-mm-long channel, 7-channel hybrid module is chosen to dissipate heat.

KW - Gaussian form heat flux

KW - geometry parametric effect

KW - slot jet/minichannel hybrid heat sink

KW - thermal resistance

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DO - 10.1615/HeatTransRes.2021039863

M3 - Article

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SN - 1064-2285

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SP - 39

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JO - Heat Transfer Research

JF - Heat Transfer Research

IS - 18

ER -

THERMAL ANALYSIS AND OPTIMIZATION OF HIGH-POWER BEAM DEPOSITION TARGET COOLING HEAT SINK FOR ACCELERATOR RADIOISOTOPES APPLICATION

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