Experimental Investigation of Thin PCM Packages and Thermal Spreader for Thermal Management of Portable Electronic Devices

As the size of portable electronic devices, like tablet computers or smartphones, continues to decrease and their performance continues to increase, thermal management of the generated heat is becoming an ever more important issue. Phase change materials (PCMs) integration is a promising approach to...

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Bibliographic Details
Published inApplied sciences Vol. 9; no. 21; p. 4613
Main Authors Maranda, Simon, Sponagle, Benjamin, Worlitschek, Jörg, Groulx, Dominic
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.11.2019
Subjects
Aluminum
Computer industry
Computers
Cooling
Electronic components
Electronic equipment
experimental investigation
Heat
Integration
Lauric acid
Metal sheets
Overheating
Packages
Personal computers
phase change material (pcm)
Phase change materials
Phase transitions
Portable computers
portable electronics
Portable equipment
Smartphones
Tablet computers
Temperature
temperature control
Thermal management
thermal storage
Thickness
Transistors
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Summary:As the size of portable electronic devices, like tablet computers or smartphones, continues to decrease and their performance continues to increase, thermal management of the generated heat is becoming an ever more important issue. Phase change materials (PCMs) integration is a promising approach to reduce overheating of electronic components in tablet design while keeping the temperature of the cover surface within a comfortable range. This work focuses on the experimental thermal investigation of thin encapsulated PCM packages in combination with a thermal spreader as a solution for thermal management in portable electronic devices. The packages had an overall thickness of less than 2 mm in order to meet the requirements for integration in thin portable electronic devices. A simplified setup at a scale similar to a modern tablet computer was used for the experimental investigations. Experiments were conducted to study, for the first time, the local thermal behavior of the thin packages and their influence on the temperature increase of the heat source and cover surface. Two different PCMs were tested: n-eicosane and dodecanoic acid. An aluminum sheet with a thickness of 0.4 mm was used as a thermal spreader. It was determined that the combination of a spreader and the thin PCM packages led to substantial reduction of the temperature increase of both the heater and the cover. Compared to the case where neither a spreader nor a PCM package was used, the heater and cover maximum temperatures were reduced by 45% and 42%, respectively, when a constant heat power input of 5 W for 60 min was applied.
ISSN:2076-3417
2076-3417
DOI:10.3390/app9214613