Computational Analysis of Pin-Fin Arrays Effects on Internal Heat Transfer Enhancement of a Blade Tip Wall
(2010) In Journal of Heat Transfer 132(3).- Abstract
- Cooling methods are strongly needed for the turbine blade tips to ensure a long durability and safe operation. Improving the internal convective cooling is therefore required to increase the blade tip life. A common way to cool the tip is to use serpentine passages with 180-deg turns under the blade tip cap. In this paper, enhanced heat transfer of a blade tip cap has been investigated numerically. The computational models consist of a two-pass channel with a 180-deg turn and various arrays of pin fins mounted on the tip cap, and a smooth two-pass channel. The inlet Reynolds number is ranging from 100,000 to 600,000. The computations are 3D, steady, incompressible, and nonrotating. Details of the 3D fluid flow and heat transfer over the... (More)
- Cooling methods are strongly needed for the turbine blade tips to ensure a long durability and safe operation. Improving the internal convective cooling is therefore required to increase the blade tip life. A common way to cool the tip is to use serpentine passages with 180-deg turns under the blade tip cap. In this paper, enhanced heat transfer of a blade tip cap has been investigated numerically. The computational models consist of a two-pass channel with a 180-deg turn and various arrays of pin fins mounted on the tip cap, and a smooth two-pass channel. The inlet Reynolds number is ranging from 100,000 to 600,000. The computations are 3D, steady, incompressible, and nonrotating. Details of the 3D fluid flow and heat transfer over the tip walls are presented. The effects of pin-fin height, diameter, and pitches on the heat transfer enhancement on the blade tip walls are observed. The overall performances of ten models are compared and evaluated. It is found that due to the combination of turning, impingement, and pin-fin crossflow, the heat transfer coefficient of the pin-finned tip is a factor of 2.67 higher than that of a smooth tip. This augmentation is achieved at the expense of a penalty of pressure drop around 30%. Results show that the intensity of heat transfer enhancement depends upon pin-fin configuration and arrangement. It is suggested that pin fins could be used to enhance the blade tip heat transfer and cooling. (Less)
Please use this url to cite or link to this publication:
https://lup.lub.lu.se/record/1547807
- author
- Xie, Gongnan LU ; Sundén, Bengt LU ; Utriainen, Esa and Wang, Lieke
- organization
- publishing date
- 2010
- type
- Contribution to journal
- publication status
- published
- subject
- keywords
- engines, cooling, channel flow, convection, gas turbines
- in
- Journal of Heat Transfer
- volume
- 132
- issue
- 3
- article number
- 031901
- publisher
- American Society Of Mechanical Engineers (ASME)
- external identifiers
-
- wos:000273365100011
- scopus:77955290905
- ISSN
- 0022-1481
- DOI
- 10.1115/1.4000053
- language
- English
- LU publication?
- yes
- id
- 0f5c1a70-172a-4a56-81cc-0f26432af7d1 (old id 1547807)
- date added to LUP
- 2016-04-01 14:21:58
- date last changed
- 2022-02-04 20:31:09
@article{0f5c1a70-172a-4a56-81cc-0f26432af7d1, abstract = {{Cooling methods are strongly needed for the turbine blade tips to ensure a long durability and safe operation. Improving the internal convective cooling is therefore required to increase the blade tip life. A common way to cool the tip is to use serpentine passages with 180-deg turns under the blade tip cap. In this paper, enhanced heat transfer of a blade tip cap has been investigated numerically. The computational models consist of a two-pass channel with a 180-deg turn and various arrays of pin fins mounted on the tip cap, and a smooth two-pass channel. The inlet Reynolds number is ranging from 100,000 to 600,000. The computations are 3D, steady, incompressible, and nonrotating. Details of the 3D fluid flow and heat transfer over the tip walls are presented. The effects of pin-fin height, diameter, and pitches on the heat transfer enhancement on the blade tip walls are observed. The overall performances of ten models are compared and evaluated. It is found that due to the combination of turning, impingement, and pin-fin crossflow, the heat transfer coefficient of the pin-finned tip is a factor of 2.67 higher than that of a smooth tip. This augmentation is achieved at the expense of a penalty of pressure drop around 30%. Results show that the intensity of heat transfer enhancement depends upon pin-fin configuration and arrangement. It is suggested that pin fins could be used to enhance the blade tip heat transfer and cooling.}}, author = {{Xie, Gongnan and Sundén, Bengt and Utriainen, Esa and Wang, Lieke}}, issn = {{0022-1481}}, keywords = {{engines; cooling; channel flow; convection; gas turbines}}, language = {{eng}}, number = {{3}}, publisher = {{American Society Of Mechanical Engineers (ASME)}}, series = {{Journal of Heat Transfer}}, title = {{Computational Analysis of Pin-Fin Arrays Effects on Internal Heat Transfer Enhancement of a Blade Tip Wall}}, url = {{http://dx.doi.org/10.1115/1.4000053}}, doi = {{10.1115/1.4000053}}, volume = {{132}}, year = {{2010}}, }