SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2078393875> ?p ?o ?g. }

Showing items 1 to 100 of ±114 with 100 items per page.

W2078393875 endingPage "275" @default.
W2078393875 startingPage "264" @default.
W2078393875 abstract "Micro thermal systems are convenient cooling devices for high heat flux applications. Besides, the nanofluids are used to improve the cooling capabilities. The suspended nanoparticles in the base fluid increase the thermal conductivity, fluid viscosity and fluid density but decrease the effective heat capacity. To analyze the suitability of using the nanofluids for cooling applications, the numerical simulations are made for nanofluid heat transfer and fluid flow in micro-heat sink with straight microtubes and multiple tangential inlet jets. The configurations with five inlet jets is considered and numerical simulations are based on a finite volume method. The Al2O3 water based nanofluid was used in simulations. The heat flux spread through the bottom surface of the heat sink was q = 50 W/cm2. Re from 15 to 100 was considered to simulate the laminar fluid flow. The analysis is based on thermal and hydrodynamic results obtained for nanofluid and compared with results obtained for water. The results are analyzed on a fixed pumping power, Re or mass flow rate basis. It is observed that the conclusions are strongly dependent on the analysis constraint. Moreover the surface temperature difference is not very much improved by using the nanofluid." @default.
W2078393875 created "2016-06-24" @default.
W2078393875 creator A5067090919 @default.
W2078393875 creator A5081392696 @default.
W2078393875 date "2014-02-01" @default.
W2078393875 modified "2023-10-05" @default.
W2078393875 title "The water based Al2O3 nanofluid flow and heat transfer in tangential microtube heat sink with multiple inlets" @default.
W2078393875 cites W1795761821 @default.
W2078393875 cites W1974916268 @default.
W2078393875 cites W1981579766 @default.
W2078393875 cites W1983829324 @default.
W2078393875 cites W1985530709 @default.
W2078393875 cites W1987491466 @default.
W2078393875 cites W1991457271 @default.
W2078393875 cites W1993774464 @default.
W2078393875 cites W1994088545 @default.
W2078393875 cites W1996373652 @default.
W2078393875 cites W1996588717 @default.
W2078393875 cites W1998585101 @default.
W2078393875 cites W1999045725 @default.
W2078393875 cites W2001680699 @default.
W2078393875 cites W2001969570 @default.
W2078393875 cites W2002948299 @default.
W2078393875 cites W2003852242 @default.
W2078393875 cites W2007489405 @default.
W2078393875 cites W2014102085 @default.
W2078393875 cites W2014453294 @default.
W2078393875 cites W2015368867 @default.
W2078393875 cites W2018807173 @default.
W2078393875 cites W2018931720 @default.
W2078393875 cites W2023961666 @default.
W2078393875 cites W2027792859 @default.
W2078393875 cites W2028220354 @default.
W2078393875 cites W2032908964 @default.
W2078393875 cites W2033448214 @default.
W2078393875 cites W2034716737 @default.
W2078393875 cites W2034929054 @default.
W2078393875 cites W2038127016 @default.
W2078393875 cites W2041597166 @default.
W2078393875 cites W2044220798 @default.
W2078393875 cites W2044433392 @default.
W2078393875 cites W2046092162 @default.
W2078393875 cites W2048541949 @default.
W2078393875 cites W2065184064 @default.
W2078393875 cites W2066668603 @default.
W2078393875 cites W2072777092 @default.
W2078393875 cites W2077967289 @default.
W2078393875 cites W2079476849 @default.
W2078393875 cites W2087622678 @default.
W2078393875 cites W2094283499 @default.
W2078393875 cites W2111407322 @default.
W2078393875 cites W2114031783 @default.
W2078393875 cites W2140866824 @default.
W2078393875 cites W2144505978 @default.
W2078393875 cites W2156259175 @default.
W2078393875 doi "https://doi.org/10.1016/j.ijheatmasstransfer.2013.10.026" @default.
W2078393875 hasPublicationYear "2014" @default.
W2078393875 type Work @default.
W2078393875 sameAs 2078393875 @default.
W2078393875 citedByCount "35" @default.
W2078393875 countsByYear W20783938752014 @default.
W2078393875 countsByYear W20783938752015 @default.
W2078393875 countsByYear W20783938752016 @default.
W2078393875 countsByYear W20783938752017 @default.
W2078393875 countsByYear W20783938752018 @default.
W2078393875 countsByYear W20783938752019 @default.
W2078393875 countsByYear W20783938752020 @default.
W2078393875 countsByYear W20783938752021 @default.
W2078393875 countsByYear W20783938752022 @default.
W2078393875 crossrefType "journal-article" @default.
W2078393875 hasAuthorship W2078393875A5067090919 @default.
W2078393875 hasAuthorship W2078393875A5081392696 @default.
W2078393875 hasConcept C121332964 @default.
W2078393875 hasConcept C159188206 @default.
W2078393875 hasConcept C159985019 @default.
W2078393875 hasConcept C186937647 @default.
W2078393875 hasConcept C192562407 @default.
W2078393875 hasConcept C21946209 @default.
W2078393875 hasConcept C50517652 @default.
W2078393875 hasConcept C57879066 @default.
W2078393875 hasConcept C76563973 @default.
W2078393875 hasConcept C97346530 @default.
W2078393875 hasConcept C97355855 @default.
W2078393875 hasConceptScore W2078393875C121332964 @default.
W2078393875 hasConceptScore W2078393875C159188206 @default.
W2078393875 hasConceptScore W2078393875C159985019 @default.
W2078393875 hasConceptScore W2078393875C186937647 @default.
W2078393875 hasConceptScore W2078393875C192562407 @default.
W2078393875 hasConceptScore W2078393875C21946209 @default.
W2078393875 hasConceptScore W2078393875C50517652 @default.
W2078393875 hasConceptScore W2078393875C57879066 @default.
W2078393875 hasConceptScore W2078393875C76563973 @default.
W2078393875 hasConceptScore W2078393875C97346530 @default.
W2078393875 hasConceptScore W2078393875C97355855 @default.
W2078393875 hasLocation W20783938751 @default.
W2078393875 hasOpenAccess W2078393875 @default.
W2078393875 hasPrimaryLocation W20783938751 @default.
W2078393875 hasRelatedWork W1982607390 @default.