Publication:
Direct liquid cooling of high flux LED systems: hot spot abatement

dc.contributor.authorTamdoğan, Enes
dc.contributor.authorArık, Mehmet
dc.contributor.authorDoğruöz, M. B.
dc.contributor.departmentMechanical Engineering
dc.contributor.ozuauthorARIK, Mehmet
dc.contributor.ozuauthorTAMDOĞAN, Enes
dc.contributor.ozugradstudentTamdoğan, Enes
dc.date.accessioned2016-02-17T06:33:24Z
dc.date.available2016-02-17T06:33:24Z
dc.date.issued2013
dc.descriptionDue to copyright restrictions, the access to the full text of this article is only available via subscription.
dc.description.abstractWith the recent advances in wide band gap device technology, solid-state lighting (SSL) has become favorable for many lighting applications due to energy savings, long life, green nature for environment, and exceptional color performance. Light emitting diodes (LED) as SSL devices have recently offered unique advantages for a wide range of commercial and residential applications. However, LED operation is strictly limited by temperature as its preferred chip junction temperature is below 100 °C. This is very similar to advanced electronics components with continuously increasing heat fluxes due to the expanding microprocessor power dissipation coupled with reduction in feature sizes. While in some of the applications standard cooling techniques cannot achieve an effective cooling performance due to physical limitations or poor heat transfer capabilities, development of novel cooling techniques is necessary. The emergence of LED hot spots has also turned attention to the cooling with dielectric liquids intimately in contact with the heat and photon dissipating surfaces, where elevated LED temperatures will adversely affect light extraction and reliability. In the interest of highly effective heat removal from LEDs with direct liquid cooling, the current paper starts with explaining the increasing thermal problems in electronics and also in lighting technologies followed by a brief overview of the state of the art for liquid cooling technologies. Then, attention will be turned into thermal consideration of approximately a 60W replacement LED light engine. A conjugate CFD model is deployed to determine local hot spots and to optimize the thermal resistance by varying multiple design parameters, boundary conditions, and the type of fluid. Detailed system level simulations also point out possible abatement techniques for local hot spots while keeping light extraction at maximum.
dc.identifier.doi10.1115/IPACK2013-73031
dc.identifier.isbn978-0-7918-5576-8
dc.identifier.scopus2-s2.0-84894655074
dc.identifier.urihttp://hdl.handle.net/10679/2765
dc.identifier.urihttps://doi.org/10.1115/IPACK2013-73031
dc.identifier.volume2
dc.identifier.wos000361499700002
dc.language.isoengen_US
dc.peerreviewedyes
dc.publicationstatuspublisheden_US
dc.publisherASME
dc.relation.ispartofASME 2013 International Technical Conference and Exhibition on Packaging and Integration of Electronic and Photonic Microsystems
dc.relation.publicationcategoryInternational
dc.rightsrestrictedAccess
dc.subject.keywordsLight emitting diodes
dc.subject.keywordsLight emitting diodes
dc.subject.keywordsLEDs
dc.subject.keywordsLiquid cooling
dc.subject.keywordsThermal management
dc.subject.keywordsThermal management
dc.subject.keywordsElectronics cooling
dc.subject.keywordsDesign optimization
dc.titleDirect liquid cooling of high flux LED systems: hot spot abatementen_US
dc.typeconferenceObjecten_US
dspace.entity.typePublication
relation.isOrgUnitOfPublicationdaa77406-1417-4308-b110-2625bf3b3dd7
relation.isOrgUnitOfPublication.latestForDiscoverydaa77406-1417-4308-b110-2625bf3b3dd7

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