Film cooling performance of converging slot-hole rows on a gas turbine blade.

Author(s) : LIU C. L., ZHU H. R., BAI J. T., et al.

Type of article: Article

Summary

Experimental tests have been performed to investigate the film cooling performance of converging slothole (console) rows on the turbine blade. Film cooling effectiveness of each single hole row is measured under three momentum flux ratios based on the wide-band liquid crystal technique. Measurements of the cooling effectiveness with all the hole rows open are also carried out under two coolant-mainstream flux ratios. Film cooling effectiveness of cylindrical hole rows on the same blade model is measured as a comparison. The results reveal that the trace of jets from both consoles and cylindrical holes is converging on the suction surface and expanding on the pressure surface by the influence of the passage vortex, while the influence of passage vortex on the jets from consoles is weaker. The film coverage area and the film cooling effectiveness of single/multiple console row(s) are much larger than those of single/multiple cylindrical hole row(s). When the console row is discrete and the diffusion angle of the console is not very large, the adjacent jets cannot connect immediately after ejecting out of the holes and the cooling effectiveness in the region between adjacent holes is relatively lower. On the pressure surface, the film cooling effectiveness of console rows increases notably with the increasing of momentum flux ratio or coolant-mainstream flux ratio. But on the suction side, the increase in cooling effectiveness is not very notable for console row film cooling as the coolant flux increases. Moreover, for the film cooling of single console row at the gill region of the suction surface, the jets could lift off from the blade surface because of the convex geometry of the suction surface. [Reprinted with permission from Elsevier. Copyright, 2010].

Details

  • Original title: Film cooling performance of converging slot-hole rows on a gas turbine blade.
  • Record ID : 2011-0075
  • Languages: English
  • Source: International Journal of Heat and Mass Transfer - vol. 53 - n. 23-24
  • Publication date: 2010/11
  • DOI: http://dx.doi.org/10.1016/j.ijheatmasstransfer.2010.07.036

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