SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2364684546> ?p ?o ?g. }

Showing items 1 to 100 of ±134 with 100 items per page.

W2364684546 endingPage "427" @default.
W2364684546 startingPage "407" @default.
W2364684546 abstract "Abstract Most of the energy related applications are involved with heat transfer and fluid flow, and the efficient utilization of energy system is always a matter of great importance. With a simple flow geometry, the present work is devoted to report a better thermal energy transfer utilizing an adiabatic block in a sidewalls moving, differentially-heated cavity. The study demonstrates the effective role of the adiabatic block on energy transport from source to sink. The adiabatic block, depending on the situations, both favors and hinders overall heat transfer of the system. The size of the block decides the modality of thermal energy transfer. In this work, different speeds and configurations of wall motion are investigated exhaustively to assess the extent of heat transfer augmentation and the optimal block sizes. The results indicate that, up to a certain block size, the thermal energy transport of this cavity enhances. Heat transfer augmentation is remarkably high for opposing flow situation. The dynamics of energy flow from the source to the sink is presented using heatfunction that reveals the evolution of energy recirculation cells in the cavity. The presence of an adiabatic block potentially suppresses this energy recirculation. The evolved vortical flow structure in the cavity is explained using elliptical and hyperbolic points. The study is further extended to include the impact of cavity inclination on the thermal performance." @default.
W2364684546 created "2016-06-24" @default.
W2364684546 creator A5025552283 @default.
W2364684546 creator A5056355624 @default.
W2364684546 creator A5069535602 @default.
W2364684546 date "2016-09-01" @default.
W2364684546 modified "2023-09-23" @default.
W2364684546 title "Enhanced thermal energy transport using adiabatic block inside lid-driven cavity" @default.
W2364684546 cites W1148157940 @default.
W2364684546 cites W1965038369 @default.
W2364684546 cites W1973729729 @default.
W2364684546 cites W1975754514 @default.
W2364684546 cites W1976362034 @default.
W2364684546 cites W1976673811 @default.
W2364684546 cites W1978424434 @default.
W2364684546 cites W1979224016 @default.
W2364684546 cites W1980899730 @default.
W2364684546 cites W1987425571 @default.
W2364684546 cites W1988901770 @default.
W2364684546 cites W1989666964 @default.
W2364684546 cites W1990366836 @default.
W2364684546 cites W1992194873 @default.
W2364684546 cites W2003228208 @default.
W2364684546 cites W2004684317 @default.
W2364684546 cites W2007988626 @default.
W2364684546 cites W2010341103 @default.
W2364684546 cites W2015465361 @default.
W2364684546 cites W2015699803 @default.
W2364684546 cites W2020173235 @default.
W2364684546 cites W2020711714 @default.
W2364684546 cites W2021654055 @default.
W2364684546 cites W2023356826 @default.
W2364684546 cites W2024931435 @default.
W2364684546 cites W2024932337 @default.
W2364684546 cites W2028416837 @default.
W2364684546 cites W2029341434 @default.
W2364684546 cites W2029569632 @default.
W2364684546 cites W2029852574 @default.
W2364684546 cites W2032040412 @default.
W2364684546 cites W2033409498 @default.
W2364684546 cites W2034698006 @default.
W2364684546 cites W2035946006 @default.
W2364684546 cites W2042328516 @default.
W2364684546 cites W2042715672 @default.
W2364684546 cites W2043647345 @default.
W2364684546 cites W2046683808 @default.
W2364684546 cites W2049838170 @default.
W2364684546 cites W2050351043 @default.
W2364684546 cites W2050494704 @default.
W2364684546 cites W2053317324 @default.
W2364684546 cites W2054972447 @default.
W2364684546 cites W2056183386 @default.
W2364684546 cites W2056739615 @default.
W2364684546 cites W2067707298 @default.
W2364684546 cites W2072333266 @default.
W2364684546 cites W2073165743 @default.
W2364684546 cites W2074611378 @default.
W2364684546 cites W2078004587 @default.
W2364684546 cites W2079159423 @default.
W2364684546 cites W2088124580 @default.
W2364684546 cites W2089922930 @default.
W2364684546 cites W2093717036 @default.
W2364684546 cites W2095626383 @default.
W2364684546 cites W2097817524 @default.
W2364684546 cites W2099136562 @default.
W2364684546 cites W2104502004 @default.
W2364684546 cites W2116919966 @default.
W2364684546 cites W2124528883 @default.
W2364684546 cites W2130139163 @default.
W2364684546 cites W2161727252 @default.
W2364684546 cites W252722256 @default.
W2364684546 cites W615409308 @default.
W2364684546 cites W623510916 @default.
W2364684546 doi "https://doi.org/10.1016/j.ijheatmasstransfer.2016.04.074" @default.
W2364684546 hasPublicationYear "2016" @default.
W2364684546 type Work @default.
W2364684546 sameAs 2364684546 @default.
W2364684546 citedByCount "48" @default.
W2364684546 countsByYear W23646845462016 @default.
W2364684546 countsByYear W23646845462017 @default.
W2364684546 countsByYear W23646845462018 @default.
W2364684546 countsByYear W23646845462019 @default.
W2364684546 countsByYear W23646845462020 @default.
W2364684546 countsByYear W23646845462021 @default.
W2364684546 countsByYear W23646845462022 @default.
W2364684546 countsByYear W23646845462023 @default.
W2364684546 crossrefType "journal-article" @default.
W2364684546 hasAuthorship W2364684546A5025552283 @default.
W2364684546 hasAuthorship W2364684546A5056355624 @default.
W2364684546 hasAuthorship W2364684546A5069535602 @default.
W2364684546 hasConcept C107861326 @default.
W2364684546 hasConcept C109663097 @default.
W2364684546 hasConcept C121332964 @default.
W2364684546 hasConcept C186370098 @default.
W2364684546 hasConcept C192562407 @default.
W2364684546 hasConcept C204530211 @default.
W2364684546 hasConcept C2524010 @default.
W2364684546 hasConcept C2777210771 @default.