Publicado 18 números por año
ISSN Imprimir: 1064-2285
ISSN En Línea: 2162-6561
IF:
1.7
5-Year IF:
1.4
Immediacy Index:
0.6
Eigenfactor:
0.00072
JCI:
0.43
SJR:
0.318
SNIP:
0.568
CiteScore™::
3.5
H-Index:
28
Indexed in
Augmented Heat Transfer of an Internal Blade Tip by Full or Partial Arrays of Pin-Fins
Get access
SINOPSIS
Cooling methods are needed for the turbine blade tips to ensure a long durability and safe operation. A common way to cool the tip is to design serpentine passages with 180-deg turn under the blade tip- cap taking advantage of the three-dimensional turning effect and impingement like flow. Improved internal convective cooling is therefore required to increase the blade tip life. In the present study, augmented heat transfer of an internal blade tip by pin-fins has been investigated numerically. The computational models consist of a two-pass channel with 180-deg turn and an array of pin-fins mounted on the tip-cap, and a smooth-tip two-pass channel. The computational domain includes the fluid region and the solid pins as well as the tip regions. Turbulent convective heat transfer between the fluid and pins, and heat conduction within pins and tip are simultaneously computed. The main objective of the present study is to observe the effect of the full and partial pin-fins arrays on heat transfer enhancement of pin-finned tips. Results show that due to the combination of turning impingement and pin-fin crossflow, the maximum heat transfer coefficient of the full and partial pin-finned tip is a factor of 3.0 and 1.8, respectively, higher than that of a smooth tip. Disregarding the increased active heat transfer area, the tip with partial pin-fins array provides around 6% higher heat transfer enhancement than the tip with full pin-fins array. It is suggested that the use of partial pin-fins array is suitable for improving blade tip cooling when the added weight and thereby the increased stress on a blade are considered.
-
Xie Gongnan, Zhang Weihong, Sunden Bengt, Computational analysis of the influences of guide ribs/vanes on enhanced heat transfer of a turbine blade tip-wall, International Journal of Thermal Sciences, 51, 2012. Crossref
-
Xie Gongnan, Sundén Bengt, Zhang Weihong, Comparisons of Pins/Dimples/Protrusions Cooling Concepts for a Turbine Blade Tip-Wall at High Reynolds Numbers, Journal of Heat Transfer, 133, 6, 2011. Crossref
-
Rimza Sandeep, Khirwadkar Samir, Velusamy Karuppanna, An experimental and numerical study of flow and heat transfer in helium cooled divertor finger mock-up with sectorial extended surface, Applied Thermal Engineering, 82, 2015. Crossref
-
Rimza Sandeep, Satpathy Kamalakanta, Khirwadkar Samir, Velusamy Karupanna, Optimal design of divertor heat sink with different geometric configurations of sectorial extended surfaces, Fusion Engineering and Design, 100, 2015. Crossref
-
Zhang Di, Jing Qi, Xie Yonghui, Shen Zhongyang, Numerical prediction on turbine blade internal tip cooling with pin-fin and dimple/protrusion structures, Numerical Heat Transfer, Part A: Applications, 70, 9, 2016. Crossref
-
Xie Gongnan, Sundén Bengt, Wang Qiuwang, Predictions of Enhanced Heat Transfer of an Internal Blade Tip-Wall With Hemispherical Dimples or Protrusions, Journal of Turbomachinery, 133, 4, 2011. Crossref
-
Imdad Aaqib, Ali Hassan, Farooq Haroon, Ali Hafiz, Effect of condensate flow rate, surface tension, density and vapor velocity on condensate retention of wire wrapped tubes, Thermal Science, 26, 1 Part B, 2022. Crossref