Fabrication and evaluation of a high-performance flexible pulsating heat pipe hermetically sealed with metal

•A method for fabricating a high-performance FPHP hermetically sealed with metal is proposed.•The thermal performance of the FPHP is approximately 2.7 times higher than that of copper.•The long-term reliability of the FPHP is evaluated by using the pressure rise method to measure the gas permeabilit...

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Bibliographic Details
Published in:International journal of heat and mass transfer 2020-03, Vol.149, p.119180, Article 119180
Main Authors: Jung, Chuljae, Lim, Jonghyun, Kim, Sung Jin
Format: Article
Language:English
Subjects:
Copper
Diameters
Engraving
Flanges
Flexible heat spreader
Foils
Heat conductivity
Heat pipes
Heat transfer
Horizontal orientation
Laminates
Long-term reliability
Performance evaluation
Permeability
Polycarbonate resins
Pulsating heat pipe
Reliability analysis
Reliability aspects
Silane-mediated bonding method
Soldering
Thermal conductivity
Thermal performance
Vertical orientation
Working fluids
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Summary:•A method for fabricating a high-performance FPHP hermetically sealed with metal is proposed.•The thermal performance of the FPHP is approximately 2.7 times higher than that of copper.•The long-term reliability of the FPHP is evaluated by using the pressure rise method to measure the gas permeability. A high-performance flexible pulsating heat pipe (FPHP) hermetically sealed with metal has been developed as a flexible heat spreader. For this, experimental works are conducted to evaluate the thermal performance and long-term reliability of the FPHP. The FPHP consisted of a polycarbonate sheet and flexible-copper-clad-laminates (FCCLs). Rectangular channels with dual hydraulic diameters of 0.75 mm and 0.5 mm were engraved on the polycarbonate sheet. The width, length, and thickness of the FPHP were 53.4 mm, 85.5 mm, and 0.64 mm, respectively. To prevent the permeation of non-condensable gases (NGCs) from the ambient, the upper and lower sides of the channel wall were encapsulated with the copper side of the FCCLs by a silane-mediated bonding method, and the flanges of the FPHP were sealed by soldering the two copper-foils. As the working fluid, HFE-7000 was charged into the FPHP. The FPHP has a maximum effective thermal conductivity of 1070 W/m⋅K, which is approximately 2.7 times higher than that of copper in the vertical orientation. The effective thermal conductivity of the FPHP decreases by 20.4% and 3.4% for the horizontal orientation and 45-degree bent condition, respectively. The long-term reliability of the FPHP was evaluated by measuring its gas permeability. The results show that the rate of the pressure increase inside the FPHP is approximately 0.54 Pa/day, indicating that the lifetime of the FPHP is at least 2000 days. The proposed method enables the fabrication of a thin and flexible pulsating heat pipe with high thermal performance and guaranteed long-term reliability.
ISSN:0017-9310
1879-2189
DOI:10.1016/j.ijheatmasstransfer.2019.119180