INSTITUTIONAL DIGITAL REPOSITORY

Mitigating non‐uniform heat generation induced hot spot(s) in multicore processors using nanofluids in parallel microchannels

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dc.contributor.author Maganti, L.S.
dc.contributor.author Dhar, P.
dc.contributor.author Sundararajan, T.
dc.contributor.author Das, S.K.
dc.date.accessioned 2019-01-01T06:52:06Z
dc.date.available 2019-01-01T06:52:06Z
dc.date.issued 2019-01-01
dc.identifier.uri http://localhost:8080/xmlui/handle/123456789/1173
dc.description.abstract The present paper illustrates experimentally the impact of non-uniform heat generation in a microprocessor on the hot spot distribution and the method to cool the same, efficiently employing parallel microchannel cooling configurations. It is often assumed during design of microprocessor cooling systems that the heat load emitted by the device is uniform, however real time tracking of the device shows that such assumptions are far from the reality. An Intel® Core™ i7–4770 3.40 GHz quad core processor has been experimentally mimicked using heat load data retrieved from a real microprocessor with non-uniform core activity. Parallel microchannel based heat spreader configurations using U, I and Z type flow configurations have been employed to mitigate the thermal load from the mimicked device. The observations clearly show that the microchannel cooling system experiences two forms of hot spots, one due to the flow maldistribution within the system and the other due to the additional non-uniform heat generation by the device. The hot spots have been shown to exhibit drastically different shapes and core temperatures and this has been verified through simulations and infrared thermography. To efficiently cool hot spot core temperatures, nanofluids have been employed and ‘smart cooling’ has been observed and the same has been explained based on nanoparticle slip mechanisms. The present work shows that the notion that high flow maldistribution leads to high thermal maldistribution, is not always true and existing maldistribution can be effectively utilized to tackle specific hot spot location. The present work can be important to design cooling mechanisms for real microprocessors with high core activity leading to non-uniform hot spot formation probabilities. en_US
dc.language.iso en_US en_US
dc.subject Intel® Core™ i7–4770 en_US
dc.subject Microprocessor en_US
dc.subject Non-uniform thermal load en_US
dc.subject Parallel microchannel cooling system en_US
dc.subject Nanofluids en_US
dc.subject Flow maldistribution en_US
dc.title Mitigating non‐uniform heat generation induced hot spot(s) in multicore processors using nanofluids in parallel microchannels en_US
dc.type Article en_US


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