Laminar free convection in a square enclosure driven by the Lorentz force

dc.contributor.author	Σαρρής, Ιωάννης Ε.	el
dc.contributor.author	Γρηγοριάδης, Δ.Γ.Ε.	el
dc.contributor.author	Βλάχος, Νικόλας Σ.	el
dc.date.accessioned	2015-05-07T19:03:53Z
dc.date.available	2015-05-07T19:03:53Z
dc.date.issued	2015-05-07
dc.identifier.uri	http://hdl.handle.net/11400/9891
dc.rights	Αναφορά Δημιουργού-Μη Εμπορική Χρήση-Όχι Παράγωγα Έργα 3.0 Ηνωμένες Πολιτείες	*
dc.rights.uri	http://creativecommons.org/licenses/by-nc-nd/3.0/us/	*
dc.source	http://www.tandfonline.com/	en
dc.subject	electrically conducting fluid
dc.subject	magnetic field
dc.subject	intensity
dc.subject	Reynolds number
dc.subject	ηλεκτρικά αγώγιμο ρευστό
dc.subject	μαγνητικό πεδίο
dc.subject	ένταση
dc.subject	αριθμός Reynolds
dc.title	Laminar free convection in a square enclosure driven by the Lorentz force	en
heal.type	journalArticle
heal.classification	Technology
heal.classification	Engineering
heal.classification	Τεχνολογία
heal.classification	Μηχανική
heal.classificationURI	http://id.loc.gov/authorities/subjects/sh85133147
heal.classificationURI	http://zbw.eu/stw/descriptor/19795-3
heal.classificationURI	N/A-Τεχνολογία
heal.classificationURI	N/A-Μηχανική
heal.keywordURI	http://id.loc.gov/authorities/subjects/sh85113557
heal.identifier.secondary	DOI:10.1080/10407782.2010.529034
heal.language	en
heal.access	free
heal.publicationDate	2010
heal.bibliographicCitation	SARRIS, I.E., GRIGORIADIS, D.G.E. & VLACHOS, N.S. (2010). Laminar free convection in a square enclosure driven by the Lorentz force. Numerical Heat Transfer: Part A - Applications. [Online] 58 (12). p.923-942. Available from: http://www.tandfonline.com/[Accessed 06/12/2010]	en
heal.abstract	A numerical study is presented of laminar free convection flow driven by magnetic forces. An external magnetic field with one spatially varying component is applied to an electrically conducting fluid in a square enclosure. This magnetically-driven flow is controlled by the intensity and the wave number of the applied magnetic forcing. In addition, when the enclosure is heated laterally in a non-zero gravity environment, the resulting buoyant forces may contribute or resist the magnetically-driven fluid motion. The present results show that a strong magnetic field can even reverse the buoyant flow. The circulation intensity of the flow and the heat transfer from the sidewalls is increased with increasing magnetic field or with decreasing magnetic Reynolds number. The wave number of the magnetic forcing is also an important parameter that determines the vortex patterns and, consequently, the convection heat transfer.	en
heal.publisher	Taylor & Francis	en
heal.journalName	Numerical Heat Transfer, Part A: Applications	en
heal.journalType	peer-reviewed
heal.fullTextAvailability	true