TY - JOUR
T1 - An investigation of a multi-layered oscillating heat pipe additively manufactured from Ti-6Al-4V powder
AU - Ibrahim, Omar T.
AU - Monroe, J. Gabriel
AU - Thompson, Scott M.
AU - Shamsaei, Nima
AU - Bilheux, Hassina
AU - Elwany, Alaa
AU - Bian, Linkan
N1 - Publisher Copyright:
© 2016 Elsevier Ltd
PY - 2017
Y1 - 2017
N2 - A laser powder bed fusion (L-PBF) additive manufacturing (AM) method was employed for fabricating a multi-layered, Ti-6Al-4V oscillating heat pipe (ML-OHP). The 50.8 × 38.1 × 15.75 mm3ML-OHP consisted of four inter-connected layers of circular mini-channels, as well an integrated, hermetic-grade fill port. A series of experiments were conducted to characterize the ML-OHP thermal performance by varying power input (up to 50 W), working fluid (water, acetone, Novec™ 7200, and n-pentane), and operating orientation (vertical bottom-heating, horizontal, and vertical top-heating). The ML-OHP was found to operate effectively for all working fluids and orientations investigated, demonstrating that the OHP can function in a multi-layered form, and further indicating that one can ‘stack’ multiple, interconnected OHPs within flat media for increased thermal management. The ML-OHP evaporator size was found to depend on the layer-wise heat penetration which subsequently depends on power input and the ML-OHP design and material selection. Using neutron radiography, electron scanning microscopy and surface metrology, the ML-OHP channel structure was characterized and found to possess sintered Ti-6Al-4V powder along its periphery. The sintered channel surface, although a byproduct of the L-PBF manufacturing process, was found to behave as a secondary wicking structure for enhanced capillary pumping and wall/fluid heat transfer within the OHP. With the newfound capabilities of AM, many high heat flux thermal management devices, specifically those that employ mini- or micro-channels, can be ‘re-invented’ to possess embedded channels with atypical geometries, arrangements and surface conditions.
AB - A laser powder bed fusion (L-PBF) additive manufacturing (AM) method was employed for fabricating a multi-layered, Ti-6Al-4V oscillating heat pipe (ML-OHP). The 50.8 × 38.1 × 15.75 mm3ML-OHP consisted of four inter-connected layers of circular mini-channels, as well an integrated, hermetic-grade fill port. A series of experiments were conducted to characterize the ML-OHP thermal performance by varying power input (up to 50 W), working fluid (water, acetone, Novec™ 7200, and n-pentane), and operating orientation (vertical bottom-heating, horizontal, and vertical top-heating). The ML-OHP was found to operate effectively for all working fluids and orientations investigated, demonstrating that the OHP can function in a multi-layered form, and further indicating that one can ‘stack’ multiple, interconnected OHPs within flat media for increased thermal management. The ML-OHP evaporator size was found to depend on the layer-wise heat penetration which subsequently depends on power input and the ML-OHP design and material selection. Using neutron radiography, electron scanning microscopy and surface metrology, the ML-OHP channel structure was characterized and found to possess sintered Ti-6Al-4V powder along its periphery. The sintered channel surface, although a byproduct of the L-PBF manufacturing process, was found to behave as a secondary wicking structure for enhanced capillary pumping and wall/fluid heat transfer within the OHP. With the newfound capabilities of AM, many high heat flux thermal management devices, specifically those that employ mini- or micro-channels, can be ‘re-invented’ to possess embedded channels with atypical geometries, arrangements and surface conditions.
KW - Additive manufacturing
KW - Heat exchangers
KW - Heat spreader
KW - Heat transfer enhancement
KW - Laser sintering
KW - Minichannels
KW - Pulsating heat pipe
KW - Wicking structure
UR - http://www.scopus.com/inward/record.url?scp=85008613457&partnerID=8YFLogxK
U2 - 10.1016/j.ijheatmasstransfer.2016.12.063
DO - 10.1016/j.ijheatmasstransfer.2016.12.063
M3 - Article
AN - SCOPUS:85008613457
SN - 0017-9310
VL - 108
SP - 1036
EP - 1047
JO - International Journal of Heat and Mass Transfer
JF - International Journal of Heat and Mass Transfer
ER -