FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2009593044> ?p ?o ?g. }

• W2009593044 endingPage "2985" @default.
• W2009593044 startingPage "2977" @default.
• W2009593044 abstract "In recent years numerical solutions of the convective heat transfer equations have provided significant insight into the complex materials processing operations. However, these computational methods suffer from two major shortcomings. First, these procedures are designed to calculate temperature fields and cooling rates as output and the unidirectional structure of these solutions preclude specification of these variables as input even when their desired values are known. Second, and more important, these procedures cannot determine multiple pathways or multiple sets of input variables to achieve a particular output from the convective heat transfer equations.Here we propose a new method that overcomes the aforementioned shortcomings of the commonly used solutions of the convective heat transfer equations. The procedure combines the conventional numerical solution methods with a real number based genetic algorithm (GA) to achieve bi-directionality, i.e. the ability to calculate the required input variables to achieve a specific output such as temperature field or cooling rate. More important, the ability of the GA to find a population of solutions enables this procedure to search for and find multiple sets of input variables, all of which can lead to the desired specific output. The proposed computational procedure has been applied to convective heat transfer in a liquid layer locally heated on its free surface by an electric arc, where various sets of input variables are computed to achieve a specific fusion zone geometry defined by an equilibrium temperature. Good agreement is achieved between the model predictions and the independent experimental results, indicating significant promise for the application of this procedure in finding multiple solutions of convective heat transfer equations." @default.
• W2009593044 created "2016-06-24" @default.
• W2009593044 creator A5042272787 @default.
• W2009593044 creator A5045688288 @default.
• W2009593044 date "2005-08-05" @default.
• W2009593044 modified "2023-10-13" @default.
• W2009593044 title "A computational procedure for finding multiple solutions of convective heat transfer equations" @default.
• W2009593044 cites W1971559993 @default.
• W2009593044 cites W1976800059 @default.
• W2009593044 cites W1977520440 @default.
• W2009593044 cites W1977911496 @default.
• W2009593044 cites W1996062081 @default.
• W2009593044 cites W1997992688 @default.
• W2009593044 cites W2016122521 @default.
• W2009593044 cites W2018907165 @default.
• W2009593044 cites W2019646680 @default.
• W2009593044 cites W2020472514 @default.
• W2009593044 cites W2027594060 @default.
• W2009593044 cites W2039669437 @default.
• W2009593044 cites W2040913162 @default.
• W2009593044 cites W2064046093 @default.
• W2009593044 cites W2067694947 @default.
• W2009593044 cites W2072782187 @default.
• W2009593044 cites W2078719854 @default.
• W2009593044 cites W2079507888 @default.
• W2009593044 cites W2080412919 @default.
• W2009593044 cites W2085426270 @default.
• W2009593044 cites W2086440951 @default.
• W2009593044 cites W2086971142 @default.
• W2009593044 cites W2089022378 @default.
• W2009593044 cites W2094743848 @default.
• W2009593044 cites W2095336511 @default.
• W2009593044 cites W2131759191 @default.
• W2009593044 cites W2176119512 @default.
• W2009593044 doi "https://doi.org/10.1088/0022-3727/38/16/034" @default.
• W2009593044 hasPublicationYear "2005" @default.
• W2009593044 type Work @default.
• W2009593044 sameAs 2009593044 @default.
• W2009593044 citedByCount "36" @default.
• W2009593044 countsByYear W20095930442012 @default.
• W2009593044 countsByYear W20095930442013 @default.
• W2009593044 countsByYear W20095930442016 @default.
• W2009593044 countsByYear W20095930442019 @default.
• W2009593044 countsByYear W20095930442020 @default.
• W2009593044 countsByYear W20095930442021 @default.
• W2009593044 countsByYear W20095930442023 @default.
• W2009593044 crossrefType "journal-article" @default.
• W2009593044 hasAuthorship W2009593044A5042272787 @default.
• W2009593044 hasAuthorship W2009593044A5045688288 @default.
• W2009593044 hasConcept C10899652 @default.
• W2009593044 hasConcept C121332964 @default.
• W2009593044 hasConcept C192562407 @default.
• W2009593044 hasConcept C41231900 @default.
• W2009593044 hasConcept C50517652 @default.
• W2009593044 hasConcept C57879066 @default.
• W2009593044 hasConcept C97355855 @default.
• W2009593044 hasConceptScore W2009593044C10899652 @default.
• W2009593044 hasConceptScore W2009593044C121332964 @default.
• W2009593044 hasConceptScore W2009593044C192562407 @default.
• W2009593044 hasConceptScore W2009593044C41231900 @default.
• W2009593044 hasConceptScore W2009593044C50517652 @default.
• W2009593044 hasConceptScore W2009593044C57879066 @default.
• W2009593044 hasConceptScore W2009593044C97355855 @default.
• W2009593044 hasIssue "16" @default.
• W2009593044 hasLocation W20095930441 @default.
• W2009593044 hasOpenAccess W2009593044 @default.
• W2009593044 hasPrimaryLocation W20095930441 @default.
• W2009593044 hasRelatedWork W1964355995 @default.
• W2009593044 hasRelatedWork W2008167211 @default.
• W2009593044 hasRelatedWork W2016860363 @default.
• W2009593044 hasRelatedWork W2040154096 @default.
• W2009593044 hasRelatedWork W2057877517 @default.
• W2009593044 hasRelatedWork W2605410253 @default.
• W2009593044 hasRelatedWork W3021309486 @default.
• W2009593044 hasRelatedWork W4248367918 @default.
• W2009593044 hasRelatedWork W4365803811 @default.
• W2009593044 hasRelatedWork W1646561101 @default.
• W2009593044 hasVolume "38" @default.
• W2009593044 isParatext "false" @default.
• W2009593044 isRetracted "false" @default.
• W2009593044 magId "2009593044" @default.
• W2009593044 workType "article" @default.