Abstract
This study proposed a novel pulsating heat pipes (PHP) for high-flux thermal module. According to the open literature, the maximum value of the heat flux is 23.7 W∙cm−2 handled by PHP, which is far behind industry requirements. Therefore, the present study proposes a novel 3D PHP suitable for high heat-flux applications. The PHP were experimentally tested for different working fluids, including methanol and water. Furthermore, the experiments were performed to analyze the influence of various operating parameters, such as filling ratio (25–60%), heat load (100–800 W), and air flow rate 100–250 cubic feet per minute (CFM). The results showed that this PHP can sustain a heat flux up to 70 W∙cm−2 with the maximum case temperature under 80 °C, which is approximately three times higher than the available literature. Furthermore, the performance of the PHP module was compared against the commercial module with wicked heat pipe. The PHP exhibited about 7% higher heat dissipation compared to the commercial module. Since the proposed module uses simple copper tubes in its construction over the wicked structure used in commercial module, the novel 3D PHP module provides additional economic and mass production capability.
Original language | English |
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Article number | 120549 |
Journal | Applied Thermal Engineering |
Volume | 228 |
DOIs | |
State | Published - Jun 25 2023 |
Funding
The authors greatly acknowledge the support from Asia Vital Components Co., Ltd and a partial support from the National Science and Technology Council, Taiwan under the contract no. 111-2221-E-A49-090-MY3. The authors greatly acknowledge the support from Asia Vital Components Co. Ltd and a partial support from the National Science and Technology Council, Taiwan under the contract no. 111-2221-E-A49-090-MY3.
Funders | Funder number |
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Asia Vital Components Co. Ltd | |
National Science and Technology Council | 111-2221-E-A49-090-MY3 |
Keywords
- 3D pulsating heat pipe
- Electronic cooling
- High heat flux
- Startup time
- Water and methanol