An Experimental Investigation on Thermal Performance of Ultra-Thin Heat Pipes with Superhydrophilic Copper Braids
Journal
Heat Transfer Engineering
Journal Volume
42
Journal Issue
10
Pages
824-838
Date Issued
2021
Author(s)
Abstract
This study investigated the thermal performance of ultra-thin heat pipes (UTHPs). The total thickness of the heat pipe was 1 mm and the novel wick structure was copper braids modified to be superhydrophilic with higher capillary ability. This paper is divided into three parts, each focusing on the effect on the heat transfer performance of UTHPs, including the wettability of the wick, the filling ratio (FR), and the variation of sectional lengths. The experimental results indicate that the superhydrophilic wick structure improves the thermal performance of UTHPs, and that the FR of 16.4% results in the best thermal performance of UTHPs. Furthermore, the sectional lengths affect both the thermal resistance and the maximum heat transport capacity. The results indicate that the thermal resistance of UTHPs increases for longer adiabatic lengths but slightly decreases for longer condenser and evaporator lengths. However, because the maximum heat transport capacity is influenced by the effective length of the heat pipe, it is degraded when the adiabatic length or the condenser and evaporator length increases. An UTHP of 55-mm effective length with superhydrophilic copper braids yields thermal resistance around 0.3 (Formula presented.) /W and the best heat transport capacity of 26.3 W. ? 2020 Taylor & Francis Group, LLC.
Subjects
Evaporators; Heat pipes; Heat resistance; Superhydrophilicity; Experimental investigations; Filling ratio; Heat transport capacity; Thermal Performance; Ultra-thin; Wick structures; Heat transfer performance
Type
journal article