TY - JOUR
T1 - A system to package perspective on transient thermal management of electronics
AU - De Bock, H. Peter
AU - Huitink, David
AU - Shamberger, Patrick
AU - Lundh, James Spencer
AU - Choi, Sukwon
AU - Niedbalski, Nicholas
AU - Boteler, Lauren
N1 - Funding Information:
Office of Naval Research (ONR) (Grant No. N00014-17-1- 2802; Funder ID: 10.13039/100000006). Pennsylvania State University was provided by the AFOSR Young Investigator Program (Grant No. FA9550-17-1-0141; Funder ID: 10.13039/100008321). National Science Foundation (Grant Nos. CBET-1934482 and 2014-00555-04; Funder ID: 10.13039/100000001). U.S. Army Research Laboratory (Contract No. W911NF-17- S-0003; Funder ID: 10.13039/100006754). U.S. Army Research Laboratory's Sensors and Electron Devices Directorate (SEDD) (Cooperative Agreement No. W911NF1920276; Funder ID: 10.13039/100006754).
Publisher Copyright:
Copyright © 2020 by ASME.
PY - 2020/12
Y1 - 2020/12
N2 - There are many applications throughout the military and commercial industries whose thermal profiles are dominated by intermittent and/or periodic pulsed thermal loads. Typical thermal solutions for transient applications focus on providing sufficient continuous cooling to address the peak thermal loads as if operating under steady-state conditions. Such a conservative approach guarantees satisfying the thermal challenge but can result in significant cooling overdesign, thus increasing the size, weight, and cost of the system. Confluent trends of increasing system complexity, component miniaturization, and increasing power density demands are further exacerbating the divergence of the optimal transient and steady-state solutions. Therefore, there needs to be a fundamental shift in the way thermal and packaging engineers approach design to focus on time domain heat transfer design and solutions. Due to the application-dependent nature of transient thermal solutions, it is essential to use a codesign approach such that the thermal and packaging engineers collaborate during the design phase with application and/or electronics engineers to ensure the solution meets the requirements. This paper will provide an overview of the types of transients to consider-from the transients that occur during switching at the chip surface all the way to the system-level transients which transfer heat to air. The paper will cover numerous ways of managing transient heat including phase change materials (PCMs), heat exchangers, advanced controls, and capacitance-based packaging. Moreover, synergies exist between approaches to include application of PCMs to increase thermal capacitance or active control mechanisms that are adapted and optimized for the time constants and needs of the specific application. It is the intent of this transient thermal management review to describe a wide range of areas in which transient thermal management for electronics is a factor of significance and to illustrate which specific implementations of transient thermal solutions are being explored for each area. The paper focuses on the needs and benefits of fundamentally shifting away from a steady-state thermal design mentality to one focused on transient thermal design through application-specific, codesigned approaches.
AB - There are many applications throughout the military and commercial industries whose thermal profiles are dominated by intermittent and/or periodic pulsed thermal loads. Typical thermal solutions for transient applications focus on providing sufficient continuous cooling to address the peak thermal loads as if operating under steady-state conditions. Such a conservative approach guarantees satisfying the thermal challenge but can result in significant cooling overdesign, thus increasing the size, weight, and cost of the system. Confluent trends of increasing system complexity, component miniaturization, and increasing power density demands are further exacerbating the divergence of the optimal transient and steady-state solutions. Therefore, there needs to be a fundamental shift in the way thermal and packaging engineers approach design to focus on time domain heat transfer design and solutions. Due to the application-dependent nature of transient thermal solutions, it is essential to use a codesign approach such that the thermal and packaging engineers collaborate during the design phase with application and/or electronics engineers to ensure the solution meets the requirements. This paper will provide an overview of the types of transients to consider-from the transients that occur during switching at the chip surface all the way to the system-level transients which transfer heat to air. The paper will cover numerous ways of managing transient heat including phase change materials (PCMs), heat exchangers, advanced controls, and capacitance-based packaging. Moreover, synergies exist between approaches to include application of PCMs to increase thermal capacitance or active control mechanisms that are adapted and optimized for the time constants and needs of the specific application. It is the intent of this transient thermal management review to describe a wide range of areas in which transient thermal management for electronics is a factor of significance and to illustrate which specific implementations of transient thermal solutions are being explored for each area. The paper focuses on the needs and benefits of fundamentally shifting away from a steady-state thermal design mentality to one focused on transient thermal design through application-specific, codesigned approaches.
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U2 - 10.1115/1.4047474
DO - 10.1115/1.4047474
M3 - Article
AN - SCOPUS:85107350118
VL - 142
JO - Journal of Electronic Packaging, Transactions of the ASME
JF - Journal of Electronic Packaging, Transactions of the ASME
SN - 1043-7398
IS - 4
M1 - 041111
ER -