The development of active alloy vortex generators from shape memory alloys for the convective cooling of heated surfaces

A study of the convective heat transfer enhancement of heated surfaces through the use of active delta wing vortex generators is reported in this paper. The surface-mounted vortex generators (VGs) change their shape to intrude further into the flow at high temperatures to enhance heat transfer, whil...

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Main Authors: Aris, M.S., Owen, I, Sutcliffe, C.J.
Format: Citation Index Journal
Published: Elsevier 2011
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Online Access:http://eprints.utp.edu.my/5886/1/The_development_of_active_vortex_genreators_from_shape_memory_alloys_for_the_convective_cooling_of_heated_surfacescooling_of_rev8_JEHTformat_correction_31Jan2011.pdf
http://eprints.utp.edu.my/5886/
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spelling my.utp.eprints.58862013-02-28T02:54:44Z The development of active alloy vortex generators from shape memory alloys for the convective cooling of heated surfaces Aris, M.S. Owen, I Sutcliffe, C.J. TJ Mechanical engineering and machinery A study of the convective heat transfer enhancement of heated surfaces through the use of active delta wing vortex generators is reported in this paper. The surface-mounted vortex generators (VGs) change their shape to intrude further into the flow at high temperatures to enhance heat transfer, while maintaining a low profile at low temperatures to minimise flow pressure losses. The VGs are made from shape memory alloys and manufactured in a selective laser melting process. Experiments have been carried out in a rectangular duct supplied with laminar air flow. In the test section, a single, and a pair of active delta wing VGs were placed near the leading edge of a heated plate and tested separately for their heat transfer enhancement effects using Infrared Thermography. The pressure difference across the test section was also measured to determine the pressure drop penalty associated with the obstruction caused by the vortex generators in their active positions. Promising results were obtained for the active VGs when the surface temperatures were varied from 20o to 65oC. The vortex generators responded by increasing their angles of attack from 10o to 38o and as the designs were two-way trained, they regained their initial position and shape at a lower temperature. At their activated positions, maximum heat transfer improvements of up to 90 % and 80 % were achieved by the single and double wings respectively along the downstream direction. The flow pressure losses across the test section, when the wings were activated, increased between 7% and 63% of the losses at their de-activated positions, for the single and double VG respectively. Elsevier 2011 Citation Index Journal PeerReviewed application/pdf http://eprints.utp.edu.my/5886/1/The_development_of_active_vortex_genreators_from_shape_memory_alloys_for_the_convective_cooling_of_heated_surfacescooling_of_rev8_JEHTformat_correction_31Jan2011.pdf Aris, M.S. and Owen, I and Sutcliffe, C.J. (2011) The development of active alloy vortex generators from shape memory alloys for the convective cooling of heated surfaces. [Citation Index Journal] http://eprints.utp.edu.my/5886/
institution Universiti Teknologi Petronas
building UTP Resource Centre
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Teknologi Petronas
content_source UTP Institutional Repository
url_provider http://eprints.utp.edu.my/
topic TJ Mechanical engineering and machinery
spellingShingle TJ Mechanical engineering and machinery
Aris, M.S.
Owen, I
Sutcliffe, C.J.
The development of active alloy vortex generators from shape memory alloys for the convective cooling of heated surfaces
description A study of the convective heat transfer enhancement of heated surfaces through the use of active delta wing vortex generators is reported in this paper. The surface-mounted vortex generators (VGs) change their shape to intrude further into the flow at high temperatures to enhance heat transfer, while maintaining a low profile at low temperatures to minimise flow pressure losses. The VGs are made from shape memory alloys and manufactured in a selective laser melting process. Experiments have been carried out in a rectangular duct supplied with laminar air flow. In the test section, a single, and a pair of active delta wing VGs were placed near the leading edge of a heated plate and tested separately for their heat transfer enhancement effects using Infrared Thermography. The pressure difference across the test section was also measured to determine the pressure drop penalty associated with the obstruction caused by the vortex generators in their active positions. Promising results were obtained for the active VGs when the surface temperatures were varied from 20o to 65oC. The vortex generators responded by increasing their angles of attack from 10o to 38o and as the designs were two-way trained, they regained their initial position and shape at a lower temperature. At their activated positions, maximum heat transfer improvements of up to 90 % and 80 % were achieved by the single and double wings respectively along the downstream direction. The flow pressure losses across the test section, when the wings were activated, increased between 7% and 63% of the losses at their de-activated positions, for the single and double VG respectively.
format Citation Index Journal
author Aris, M.S.
Owen, I
Sutcliffe, C.J.
author_facet Aris, M.S.
Owen, I
Sutcliffe, C.J.
author_sort Aris, M.S.
title The development of active alloy vortex generators from shape memory alloys for the convective cooling of heated surfaces
title_short The development of active alloy vortex generators from shape memory alloys for the convective cooling of heated surfaces
title_full The development of active alloy vortex generators from shape memory alloys for the convective cooling of heated surfaces
title_fullStr The development of active alloy vortex generators from shape memory alloys for the convective cooling of heated surfaces
title_full_unstemmed The development of active alloy vortex generators from shape memory alloys for the convective cooling of heated surfaces
title_sort development of active alloy vortex generators from shape memory alloys for the convective cooling of heated surfaces
publisher Elsevier
publishDate 2011
url http://eprints.utp.edu.my/5886/1/The_development_of_active_vortex_genreators_from_shape_memory_alloys_for_the_convective_cooling_of_heated_surfacescooling_of_rev8_JEHTformat_correction_31Jan2011.pdf
http://eprints.utp.edu.my/5886/
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score 13.211869