Quantification of the impact of embedded graphite nanofibers on the transient thermal response of paraffin phase change material exposed to high heat fluxes

Kireeti Chintakrinda; Ronald J. Warzoha; Randy D. Weinstein; Amy S. Fleischer

doi:10.1115/1.4006008

Quantification of the impact of embedded graphite nanofibers on the transient thermal response of paraffin phase change material exposed to high heat fluxes

Kireeti Chintakrinda, Ronald J. Warzoha, Randy D. Weinstein, Amy S. Fleischer

Villanova University

Research output: Contribution to journal › Article › peer-review

31 Scopus citations

Abstract

Paraffin phase change material (PCM) is enhanced with suspended graphite nanofibers at high loading levels. The loading levels reach in excess of 10% by weight. The thermal effects of the nanofiber loading level, the PCM module design, and the applied power density on the transient thermal response of the system are examined. A strong effect of nanofiber loading level on thermal performance is found, including a suppression of Rayleigh-Benard convection currents at high loading levels. Increases in nanofiber loading level also result in lowered heating rates and greater thermal control of the heated base. Increases in power density are found to result in higher heating rates, and increases in mass lead to lower operating temperatures. The design of the module is found to have a strong effect on thermal performance.

Original language	English
Article number	071901
Journal	Journal of Heat Transfer
Volume	134
Issue number	7
DOIs	https://doi.org/10.1115/1.4006008
State	Published - 2012
Externally published	Yes

Keywords

electronics cooling
melting and solidification

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10.1115/1.4006008

Cite this

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title = "Quantification of the impact of embedded graphite nanofibers on the transient thermal response of paraffin phase change material exposed to high heat fluxes",

abstract = "Paraffin phase change material (PCM) is enhanced with suspended graphite nanofibers at high loading levels. The loading levels reach in excess of 10% by weight. The thermal effects of the nanofiber loading level, the PCM module design, and the applied power density on the transient thermal response of the system are examined. A strong effect of nanofiber loading level on thermal performance is found, including a suppression of Rayleigh-Benard convection currents at high loading levels. Increases in nanofiber loading level also result in lowered heating rates and greater thermal control of the heated base. Increases in power density are found to result in higher heating rates, and increases in mass lead to lower operating temperatures. The design of the module is found to have a strong effect on thermal performance.",

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author = "Kireeti Chintakrinda and Warzoha, {Ronald J.} and Weinstein, {Randy D.} and Fleischer, {Amy S.}",

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AU - Chintakrinda, Kireeti

AU - Warzoha, Ronald J.

AU - Weinstein, Randy D.

AU - Fleischer, Amy S.

PY - 2012

Y1 - 2012

N2 - Paraffin phase change material (PCM) is enhanced with suspended graphite nanofibers at high loading levels. The loading levels reach in excess of 10% by weight. The thermal effects of the nanofiber loading level, the PCM module design, and the applied power density on the transient thermal response of the system are examined. A strong effect of nanofiber loading level on thermal performance is found, including a suppression of Rayleigh-Benard convection currents at high loading levels. Increases in nanofiber loading level also result in lowered heating rates and greater thermal control of the heated base. Increases in power density are found to result in higher heating rates, and increases in mass lead to lower operating temperatures. The design of the module is found to have a strong effect on thermal performance.

AB - Paraffin phase change material (PCM) is enhanced with suspended graphite nanofibers at high loading levels. The loading levels reach in excess of 10% by weight. The thermal effects of the nanofiber loading level, the PCM module design, and the applied power density on the transient thermal response of the system are examined. A strong effect of nanofiber loading level on thermal performance is found, including a suppression of Rayleigh-Benard convection currents at high loading levels. Increases in nanofiber loading level also result in lowered heating rates and greater thermal control of the heated base. Increases in power density are found to result in higher heating rates, and increases in mass lead to lower operating temperatures. The design of the module is found to have a strong effect on thermal performance.

KW - electronics cooling

KW - melting and solidification

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DO - 10.1115/1.4006008

M3 - Article

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SN - 0022-1481

VL - 134

JO - Journal of Heat Transfer

JF - Journal of Heat Transfer

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ER -

Quantification of the impact of embedded graphite nanofibers on the transient thermal response of paraffin phase change material exposed to high heat fluxes

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Keywords

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