Energies | |
Experimental Study of Heat Transfer on the Internal Surfaces of a Double-Wall Structure with Pin Fin Array | |
Guangchao Li1  Wei Zhang2  Huiren Zhu2  | |
[1] School of Aero-Engine, Shenyang Aerospace University, Shenyang 110136, China;School of Power and Energy, Northwestern Polytechnical University, Xian 710072, China; | |
关键词: gas turbine; jet impingement; double-wall structure; full-surface temperature measurement; correction of heat transfer coefficient; heat transfer analysis; | |
DOI : 10.3390/en13246573 | |
来源: DOAJ |
【 摘 要 】
The double-wall structure is one of the most effective cooling techniques used in many engineering applications, such as turbine vane/blade, heat exchangers, etc. Heat transfer on the internal surfaces of a double-wall structure was studied at impinging Reynolds numbers ranging from 1 × 104 to 6 × 104 using the transient thermochromic liquid crystal (TLC) technique. The two-dimensional distributions of Nusselt numbers and their averaged values were obtained on the impingement surface, target surface and the pin fin surface. The Nusselt number correlations on the surfaces mentioned above were determined as a function of Reynolds number. The results show that the second peak values of the Nusselt number distribution appear on the target surface at all Reynolds numbers studied in this paper for a short distance of the target surface to impingement surface. This phenomenon becomes significant with the further increase of the Reynolds number. The difference between the Nusselt number at the second peak and the stagnation point decreases with the increasing Reynolds number. The maximal Nusselt number regions on the impingement surface appear at the left and right sides of the pin fins between the two impingement holes. The Nusselt numbers of the pin fin surfaces are highly dependent on their various locations in the double-wall structures. The contributions of the impingement surface, pin fin surface and target surface to the overall heat transfer rate are analyzed. The target surface contributed the largest amount of heat transfer rate with a value of about 62%. The heat transfer contribution is from 18% to 21% for the impingement surface and 16% to 18% for the pin fin surfaces within the studied Reynolds numbers.
【 授权许可】
Unknown