In internal cooling passages in a turbine blade, rib structures are widely applied to augment convective heat transfer by the coolant passing through over the ribbed surfaces. This study concentrates on perforated 90 deg ribs with inclined holes in a cooling duct with rectangular cross section, aiming at improving the perforated holes with additional secondary flows caused by inclined hole arrangements. Two sets of perforated ribs are used in the experiments with the inclined angle of the holes changing from 0 deg to 45 deg and the cross section are, respectively, circular and square. Steady-state liquid crystal thermography (LCT) is applied to measure the ribbed surface temperature and obtain corresponding convective heat transfer coefficients (HTCs). Two turbulence models, i.e., the k–ω shear stress transportation (SST) model and the detached eddy simulation (DES) model, are used in the numerical studies to simulate the flow fields. All the inclined cases have slightly larger overall averaged Nusselt number (Nu) than with straight cases. The enhancement ratio is approximately 1.85–4.94%. The averaged Nu in the half portion against the inclined direction is enlarged for the inclined hole cases. The inclined hole cases usually have smaller averaged Nu in the half portion along the inclined direction. For the straight hole case and small inclined angle case, the penetrated flows mix with the mainstream flows at the perforated regions. When the inclined angle is larger, the penetrated flows are pushed to the inclined direction and mixing with the approaching flows occurs just at the side of the inclined direction.
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Research-Article
Heat Transfer Enhancement and Turbulent Flow in a Rectangular Channel Using Perforated Ribs With Inclined Holes
Jian Liu,
Jian Liu
Division of Heat Transfer,
Department of Energy Sciences,
Lund University,
P.O. Box 118,
Lund SE-22100, Sweden
Department of Energy Sciences,
Lund University,
P.O. Box 118,
Lund SE-22100, Sweden
Search for other works by this author on:
Safeer Hussain,
Safeer Hussain
Division of Heat Transfer,
Department of Energy Sciences,
Lund University,
P.O. Box 118,
Lund SE-22100, Sweden
Department of Energy Sciences,
Lund University,
P.O. Box 118,
Lund SE-22100, Sweden
Search for other works by this author on:
Wei Wang,
Wei Wang
School of Energy Science and Engineering,
Harbin Institute of Technology,
Harbin 150001, China
Harbin Institute of Technology,
Harbin 150001, China
Search for other works by this author on:
Lei Wang,
Lei Wang
Division of Heat Transfer,
Department of Energy Sciences,
Lund University,
P.O. Box 118,
Lund SE-22100, Sweden
Department of Energy Sciences,
Lund University,
P.O. Box 118,
Lund SE-22100, Sweden
Search for other works by this author on:
Gongnan Xie,
Gongnan Xie
School of Marine Science and Technology,
Northwestern Polytechnical University,
Xi'an, Shaanxi 710072, China
Northwestern Polytechnical University,
Xi'an, Shaanxi 710072, China
Search for other works by this author on:
Bengt Sundén
Bengt Sundén
Division of Heat Transfer,
Department of Energy Sciences,
Lund University,
P.O. Box 118,
Lund SE-22100, Sweden
e-mail: bengt.sunden@energy.lth.se
Department of Energy Sciences,
Lund University,
P.O. Box 118,
Lund SE-22100, Sweden
e-mail: bengt.sunden@energy.lth.se
Search for other works by this author on:
Jian Liu
Division of Heat Transfer,
Department of Energy Sciences,
Lund University,
P.O. Box 118,
Lund SE-22100, Sweden
Department of Energy Sciences,
Lund University,
P.O. Box 118,
Lund SE-22100, Sweden
Safeer Hussain
Division of Heat Transfer,
Department of Energy Sciences,
Lund University,
P.O. Box 118,
Lund SE-22100, Sweden
Department of Energy Sciences,
Lund University,
P.O. Box 118,
Lund SE-22100, Sweden
Wei Wang
School of Energy Science and Engineering,
Harbin Institute of Technology,
Harbin 150001, China
Harbin Institute of Technology,
Harbin 150001, China
Lei Wang
Division of Heat Transfer,
Department of Energy Sciences,
Lund University,
P.O. Box 118,
Lund SE-22100, Sweden
Department of Energy Sciences,
Lund University,
P.O. Box 118,
Lund SE-22100, Sweden
Gongnan Xie
School of Marine Science and Technology,
Northwestern Polytechnical University,
Xi'an, Shaanxi 710072, China
Northwestern Polytechnical University,
Xi'an, Shaanxi 710072, China
Bengt Sundén
Division of Heat Transfer,
Department of Energy Sciences,
Lund University,
P.O. Box 118,
Lund SE-22100, Sweden
e-mail: bengt.sunden@energy.lth.se
Department of Energy Sciences,
Lund University,
P.O. Box 118,
Lund SE-22100, Sweden
e-mail: bengt.sunden@energy.lth.se
1Corresponding author.
Contributed by the Heat Transfer Division of ASME for publication in the JOURNAL OF HEAT TRANSFER. Manuscript received September 16, 2018; final manuscript received February 8, 2019; published online February 27, 2019. Assoc. Editor: Guihua Tang.
J. Heat Transfer. Apr 2019, 141(4): 041702 (15 pages)
Published Online: February 27, 2019
Article history
Received:
September 16, 2018
Revised:
February 8, 2019
Citation
Liu, J., Hussain, S., Wang, W., Wang, L., Xie, G., and Sundén, B. (February 27, 2019). "Heat Transfer Enhancement and Turbulent Flow in a Rectangular Channel Using Perforated Ribs With Inclined Holes." ASME. J. Heat Transfer. April 2019; 141(4): 041702. https://doi.org/10.1115/1.4042841
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