FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2005121408> ?p ?o ?g. }

• W2005121408 endingPage "363" @default.
• W2005121408 startingPage "343" @default.
• W2005121408 abstract "In this work hydrodynamics of multicomponent ideal gas mixtures have been studied. Starting from the kinetic equations, the Eulerian approach is used to derive a new set of conservation equations for the multicomponent system where each component may have different velocity and kinetic temperature. The equations are based on the Grad's method of moment derived from the kinetic model in a relaxation time approximation (RTA). Based on this model which contains separate equation sets for each component of the system, a computer code has been developed for numerical computation of compressible flows of binary gas mixture in generalized curvilinear boundary conforming coordinates. Since these equations are similar to the Navier–Stokes equations for the single fluid systems, the same numerical methods are applied to these new equations. The Roe's numerical scheme is used to discretize the convective terms of governing fluid flow equations. The prepared algorithm and the computer code are capable of computing and presenting flow fields of each component of the system separately as well as the average flow field of the multicomponent gas system as a whole. Comparison of the present code results with those of a more common algorithm based on the mixture theory in a supersonic converging–diverging nozzle provides the validation of the present formulation. Afterwards, a more involved nozzle cooling problem with a binary ideal gas (helium–xenon) is chosen to compare the present results with those of the ordinary mixture theory. The present model provides the details of the flow fields of each component separately which is not available otherwise. It is also shown that the separate fluids treatment, such as the present study, is crucial when considering time scales on the order of (or shorter than) the intercollisions relaxation times." @default.
• W2005121408 created "2016-06-24" @default.
• W2005121408 creator A5035311921 @default.
• W2005121408 creator A5070739814 @default.
• W2005121408 creator A5089745931 @default.
• W2005121408 date "2008-05-01" @default.
• W2005121408 modified "2023-09-26" @default.
• W2005121408 title "Multicomponent fluid flow analysis using a new set of conservation equations" @default.
• W2005121408 cites W1974379969 @default.
• W2005121408 cites W1977115007 @default.
• W2005121408 cites W1981193825 @default.
• W2005121408 cites W1986033790 @default.
• W2005121408 cites W1992111334 @default.
• W2005121408 cites W1999342804 @default.
• W2005121408 cites W2007231673 @default.
• W2005121408 cites W2010020145 @default.
• W2005121408 cites W2016212639 @default.
• W2005121408 cites W2053764598 @default.
• W2005121408 cites W2063714556 @default.
• W2005121408 cites W2068137389 @default.
• W2005121408 cites W2072843803 @default.
• W2005121408 cites W2076043743 @default.
• W2005121408 cites W2080429414 @default.
• W2005121408 cites W2082033078 @default.
• W2005121408 cites W2083577070 @default.
• W2005121408 doi "https://doi.org/10.1016/j.fluiddyn.2007.10.003" @default.
• W2005121408 hasPublicationYear "2008" @default.
• W2005121408 type Work @default.
• W2005121408 sameAs 2005121408 @default.
• W2005121408 citedByCount "5" @default.
• W2005121408 countsByYear W20051214082013 @default.
• W2005121408 countsByYear W20051214082014 @default.
• W2005121408 countsByYear W20051214082016 @default.
• W2005121408 countsByYear W20051214082019 @default.
• W2005121408 countsByYear W20051214082021 @default.
• W2005121408 crossrefType "journal-article" @default.
• W2005121408 hasAuthorship W2005121408A5035311921 @default.
• W2005121408 hasAuthorship W2005121408A5070739814 @default.
• W2005121408 hasAuthorship W2005121408A5089745931 @default.
• W2005121408 hasConcept C121332964 @default.
• W2005121408 hasConcept C134306372 @default.
• W2005121408 hasConcept C177264268 @default.
• W2005121408 hasConcept C199360897 @default.
• W2005121408 hasConcept C28826006 @default.
• W2005121408 hasConcept C33923547 @default.
• W2005121408 hasConcept C3445786 @default.
• W2005121408 hasConcept C38349280 @default.
• W2005121408 hasConcept C41008148 @default.
• W2005121408 hasConcept C57879066 @default.
• W2005121408 hasConcept C90278072 @default.
• W2005121408 hasConceptScore W2005121408C121332964 @default.
• W2005121408 hasConceptScore W2005121408C134306372 @default.
• W2005121408 hasConceptScore W2005121408C177264268 @default.
• W2005121408 hasConceptScore W2005121408C199360897 @default.
• W2005121408 hasConceptScore W2005121408C28826006 @default.
• W2005121408 hasConceptScore W2005121408C33923547 @default.
• W2005121408 hasConceptScore W2005121408C3445786 @default.
• W2005121408 hasConceptScore W2005121408C38349280 @default.
• W2005121408 hasConceptScore W2005121408C41008148 @default.
• W2005121408 hasConceptScore W2005121408C57879066 @default.
• W2005121408 hasConceptScore W2005121408C90278072 @default.
• W2005121408 hasIssue "5" @default.
• W2005121408 hasLocation W20051214081 @default.
• W2005121408 hasOpenAccess W2005121408 @default.
• W2005121408 hasPrimaryLocation W20051214081 @default.
• W2005121408 hasRelatedWork W1978739029 @default.
• W2005121408 hasRelatedWork W2002980787 @default.
• W2005121408 hasRelatedWork W2326627627 @default.
• W2005121408 hasRelatedWork W2335035687 @default.
• W2005121408 hasRelatedWork W2351629602 @default.
• W2005121408 hasRelatedWork W2367930678 @default.
• W2005121408 hasRelatedWork W2902027362 @default.
• W2005121408 hasRelatedWork W3138081475 @default.
• W2005121408 hasRelatedWork W4254014471 @default.
• W2005121408 hasRelatedWork W4366162493 @default.
• W2005121408 hasVolume "40" @default.
• W2005121408 isParatext "false" @default.
• W2005121408 isRetracted "false" @default.
• W2005121408 magId "2005121408" @default.
• W2005121408 workType "article" @default.