SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2321537531> ?p ?o ?g. }

Showing items 1 to 100 of ±136 with 100 items per page.

W2321537531 endingPage "956" @default.
W2321537531 startingPage "932" @default.
W2321537531 abstract "Abstract High-fidelity, direct numerical simulations (DNSs) are conducted to examine the vortex structure and aerodynamic loading of unidirectionally revolving wings in quiescent fluid. Wings with aspect ratios $({mathit{AR}}) = 1$ , 2 and 4 are considered at a fixed root-based Reynolds number of 1000. Each wing is shown to generate a coherent leading-edge vortex (LEV) that remains in close proximity to the surface and provides persistent suction throughout the motion. Towards the tip, the LEV lifts off as an arch-like structure and reorients itself along the chord through its connection with the tip vortex. The substantial and sustained aerodynamic loads achieved during the motion saturate with aspect ratio resulting from the chordwise growth of the LEV along the span eventually becoming geometrically constrained by the trailing edge. Further, for ${mathit{AR}}=4$ , substructures develop in the feeding sheet of the LEV, which appear to directly correlate with the local, span-based Reynolds number achieved during rotation. The lower-aspect-ratio wings do not have sufficient spans for these transitional elements to manifest. In contrast, vortex breakdown, which occurs around midspan for each aspect ratio, shows a strong dependence on the spanwise pressure gradient established between the root and tip of the wing and not local Reynolds number. This independent development of shear-layer substructures and vortex breakdown parallels very closely with what has been observed in delta wing flow. Next, the centrifugal, Coriolis and pressure gradient forces are also analysed at several spanwise locations across each wing, and the centrifugal and pressure gradient forces are shown to be responsible for the spanwise flow above the wing. The Coriolis force is directed away from the surface at the base of the LEV, indicating that it is not a contributor to LEV attachment, which is contrary to previous hypotheses. Finally, as a means of emphasizing the importance of the centrifugal force on LEV attachment, the ${mathit{AR}}=2$ wing is simulated with the addition of a source term in the governing equations to oppose and eliminate the centrifugal force near the surface. The initial formation and development of the LEV is unhindered by the absence of this force; however, later in the motion, the outboard lift-off of the LEV moves inboard. Without the opposing outboard-directed centrifugal force to keep the separation past midspan, the entire vortex eventually separates and moves away from the surface." @default.
W2321537531 created "2016-06-24" @default.
W2321537531 creator A5004341878 @default.
W2321537531 creator A5070733685 @default.
W2321537531 date "2014-05-12" @default.
W2321537531 modified "2023-10-17" @default.
W2321537531 title "Dynamics of revolving wings for various aspect ratios" @default.
W2321537531 cites W124993034 @default.
W2321537531 cites W1514397422 @default.
W2321537531 cites W1884981623 @default.
W2321537531 cites W1903589887 @default.
W2321537531 cites W1910119307 @default.
W2321537531 cites W1963752367 @default.
W2321537531 cites W1968785762 @default.
W2321537531 cites W1973842373 @default.
W2321537531 cites W1981202981 @default.
W2321537531 cites W2000727892 @default.
W2321537531 cites W2007082981 @default.
W2321537531 cites W2014192334 @default.
W2321537531 cites W2017231788 @default.
W2321537531 cites W2017766187 @default.
W2321537531 cites W2019482023 @default.
W2321537531 cites W2027718197 @default.
W2321537531 cites W2032990529 @default.
W2321537531 cites W2040178232 @default.
W2321537531 cites W2041167909 @default.
W2321537531 cites W2051788799 @default.
W2321537531 cites W2054884940 @default.
W2321537531 cites W2066734144 @default.
W2321537531 cites W2071014945 @default.
W2321537531 cites W2080524911 @default.
W2321537531 cites W2085756182 @default.
W2321537531 cites W2091345137 @default.
W2321537531 cites W2103606462 @default.
W2321537531 cites W2109207536 @default.
W2321537531 cites W2123766729 @default.
W2321537531 cites W2124951605 @default.
W2321537531 cites W2139035728 @default.
W2321537531 cites W2139304766 @default.
W2321537531 cites W2146385201 @default.
W2321537531 cites W2154762949 @default.
W2321537531 cites W2163070898 @default.
W2321537531 cites W2163844338 @default.
W2321537531 cites W2319313081 @default.
W2321537531 cites W2320310102 @default.
W2321537531 cites W2329415644 @default.
W2321537531 cites W2329619421 @default.
W2321537531 cites W2332585834 @default.
W2321537531 cites W3178266934 @default.
W2321537531 cites W4229790755 @default.
W2321537531 cites W4253976376 @default.
W2321537531 cites W580683601 @default.
W2321537531 doi "https://doi.org/10.1017/jfm.2014.212" @default.
W2321537531 hasPublicationYear "2014" @default.
W2321537531 type Work @default.
W2321537531 sameAs 2321537531 @default.
W2321537531 citedByCount "114" @default.
W2321537531 countsByYear W23215375312014 @default.
W2321537531 countsByYear W23215375312015 @default.
W2321537531 countsByYear W23215375312016 @default.
W2321537531 countsByYear W23215375312017 @default.
W2321537531 countsByYear W23215375312018 @default.
W2321537531 countsByYear W23215375312019 @default.
W2321537531 countsByYear W23215375312020 @default.
W2321537531 countsByYear W23215375312021 @default.
W2321537531 countsByYear W23215375312022 @default.
W2321537531 countsByYear W23215375312023 @default.
W2321537531 crossrefType "journal-article" @default.
W2321537531 hasAuthorship W2321537531A5004341878 @default.
W2321537531 hasAuthorship W2321537531A5070733685 @default.
W2321537531 hasConcept C120314980 @default.
W2321537531 hasConcept C121332964 @default.
W2321537531 hasConcept C124101348 @default.
W2321537531 hasConcept C13393347 @default.
W2321537531 hasConcept C139002025 @default.
W2321537531 hasConcept C140820882 @default.
W2321537531 hasConcept C168475990 @default.
W2321537531 hasConcept C176738000 @default.
W2321537531 hasConcept C182748727 @default.
W2321537531 hasConcept C194147245 @default.
W2321537531 hasConcept C196558001 @default.
W2321537531 hasConcept C205634578 @default.
W2321537531 hasConcept C207390838 @default.
W2321537531 hasConcept C2779570065 @default.
W2321537531 hasConcept C28317120 @default.
W2321537531 hasConcept C41008148 @default.
W2321537531 hasConcept C49040817 @default.
W2321537531 hasConcept C57879066 @default.
W2321537531 hasConcept C82558694 @default.
W2321537531 hasConcept C94531399 @default.
W2321537531 hasConcept C97257150 @default.
W2321537531 hasConcept C97355855 @default.
W2321537531 hasConcept C98156149 @default.
W2321537531 hasConceptScore W2321537531C120314980 @default.
W2321537531 hasConceptScore W2321537531C121332964 @default.
W2321537531 hasConceptScore W2321537531C124101348 @default.
W2321537531 hasConceptScore W2321537531C13393347 @default.
W2321537531 hasConceptScore W2321537531C139002025 @default.