SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2536042326> ?p ?o ?g. }

Showing items 1 to 100 of ±142 with 100 items per page.

W2536042326 endingPage "547" @default.
W2536042326 startingPage "531" @default.
W2536042326 abstract "Metal foams have gained popularity in the renewable energy industry due to their superior thermo-physical properties. In the present study, a coupled finite volume and discrete element numerical method is used to numerically investigate the mechanisms that govern particle-laden gas flows and particulate fouling in idealized metal foam air-cooled heat exchangers. This paper provides a systematic analysis of the foulant distribution and the pressure drop due to the metal foam structure and the presence of fouling. The idealized Weaire-Phelan metal foam geometry serves as a good approximation to a real metal foam geometry. The pressure drop and deposition fraction follows a linear relation for sandstone cases, whereas for the sawdust cases, the pressure drop is sensibly invariant with time although a noticeable increase in deposition fraction with time is realized. The foulant residence time in addition to the correlations between pressure drop, deposition fraction, and inlet velocity can be used to optimize metal foam heat exchanger designs. Optimum heat exchanger performance is achieved by keeping the same fiber thickness of 0.17 mm at a high porosity at 97.87%. An increase in fluid carrier velocity promotes particle transport by means of particle interception thereby reducing the deposition fraction irrespective of foam geometry." @default.
W2536042326 created "2016-10-28" @default.
W2536042326 creator A5002881487 @default.
W2536042326 creator A5033093165 @default.
W2536042326 creator A5087024415 @default.
W2536042326 creator A5091240978 @default.
W2536042326 date "2016-12-01" @default.
W2536042326 modified "2023-10-18" @default.
W2536042326 title "Numerical investigation of the temporal evolution of particulate fouling in metal foams for air-cooled heat exchangers" @default.
W2536042326 cites W10037423 @default.
W2536042326 cites W1573750563 @default.
W2536042326 cites W1964812633 @default.
W2536042326 cites W1974578866 @default.
W2536042326 cites W1979261380 @default.
W2536042326 cites W1980381105 @default.
W2536042326 cites W1983048169 @default.
W2536042326 cites W1983086030 @default.
W2536042326 cites W1985261292 @default.
W2536042326 cites W1989450587 @default.
W2536042326 cites W1989614668 @default.
W2536042326 cites W1991132417 @default.
W2536042326 cites W1992913833 @default.
W2536042326 cites W1995716638 @default.
W2536042326 cites W1996154921 @default.
W2536042326 cites W2003182915 @default.
W2536042326 cites W2008138420 @default.
W2536042326 cites W2011120264 @default.
W2536042326 cites W2012054181 @default.
W2536042326 cites W2019080222 @default.
W2536042326 cites W2019835810 @default.
W2536042326 cites W2041966969 @default.
W2536042326 cites W2042799141 @default.
W2536042326 cites W2044289176 @default.
W2536042326 cites W2049594511 @default.
W2536042326 cites W2050377411 @default.
W2536042326 cites W2052220553 @default.
W2536042326 cites W2052844847 @default.
W2536042326 cites W2058123643 @default.
W2536042326 cites W2067357808 @default.
W2536042326 cites W2073775990 @default.
W2536042326 cites W2075148084 @default.
W2536042326 cites W2078627843 @default.
W2536042326 cites W2079505091 @default.
W2536042326 cites W2081249934 @default.
W2536042326 cites W2090241924 @default.
W2536042326 cites W2094322421 @default.
W2536042326 cites W2106477680 @default.
W2536042326 cites W2111642923 @default.
W2536042326 cites W2114449970 @default.
W2536042326 cites W2117018759 @default.
W2536042326 cites W2117210950 @default.
W2536042326 cites W2123036203 @default.
W2536042326 cites W2129860564 @default.
W2536042326 cites W2168494010 @default.
W2536042326 cites W2259957531 @default.
W2536042326 cites W2277126508 @default.
W2536042326 cites W2286851149 @default.
W2536042326 cites W2304564917 @default.
W2536042326 cites W240944934 @default.
W2536042326 cites W2416812495 @default.
W2536042326 cites W2460856932 @default.
W2536042326 cites W2487363010 @default.
W2536042326 cites W325409995 @default.
W2536042326 doi "https://doi.org/10.1016/j.apenergy.2016.10.044" @default.
W2536042326 hasPublicationYear "2016" @default.
W2536042326 type Work @default.
W2536042326 sameAs 2536042326 @default.
W2536042326 citedByCount "34" @default.
W2536042326 countsByYear W25360423262017 @default.
W2536042326 countsByYear W25360423262018 @default.
W2536042326 countsByYear W25360423262019 @default.
W2536042326 countsByYear W25360423262020 @default.
W2536042326 countsByYear W25360423262021 @default.
W2536042326 countsByYear W25360423262022 @default.
W2536042326 countsByYear W25360423262023 @default.
W2536042326 crossrefType "journal-article" @default.
W2536042326 hasAuthorship W2536042326A5002881487 @default.
W2536042326 hasAuthorship W2536042326A5033093165 @default.
W2536042326 hasAuthorship W2536042326A5087024415 @default.
W2536042326 hasAuthorship W2536042326A5091240978 @default.
W2536042326 hasBestOaLocation W25360423262 @default.
W2536042326 hasConcept C107706546 @default.
W2536042326 hasConcept C114088122 @default.
W2536042326 hasConcept C115792997 @default.
W2536042326 hasConcept C116067010 @default.
W2536042326 hasConcept C121332964 @default.
W2536042326 hasConcept C127413603 @default.
W2536042326 hasConcept C159985019 @default.
W2536042326 hasConcept C1633027 @default.
W2536042326 hasConcept C185592680 @default.
W2536042326 hasConcept C192562407 @default.
W2536042326 hasConcept C204323151 @default.
W2536042326 hasConcept C2961886 @default.
W2536042326 hasConcept C41625074 @default.
W2536042326 hasConcept C47519245 @default.
W2536042326 hasConcept C55493867 @default.
W2536042326 hasConcept C57879066 @default.
W2536042326 hasConcept C6648577 @default.