Film cooling of a flat plate by one row of inclined holes located in craters at external flow acceleration

Authors

  • Артем Артемович Халатов Institute of engineering thermophysics of NAS of Ukraine 2a Zhelyabov str., Kiev, Ukraine, 03057, Ukraine
  • Игорь Иванович Борисов Institute of engineering thermophysics of NAS of Ukraine 2a Zhelyabov str., Kiev, Ukraine, 03057, Ukraine
  • Юрий Яковлевич Дашевский Gas turbine research &production complex «Zorya»–«Mashproekt» Zhovtnevyy av., 42–a, Mykolaiv City, Ukraine, 54018, Ukraine
  • Александр Сергеевич Коваленко Institute of engineering thermophysics of NAS of Ukraine 2a Zhelyabov str., Kiev, Ukraine, 03057, Ukraine
  • Сергей Владимирович Шевцов Institute of engineering thermophysics of NAS of Ukraine 2a Zhelyabov str., Kiev, Ukraine, 03057, Ukraine

DOI:

https://doi.org/10.15587/1729-4061.2013.14881

Keywords:

film cooling, holes in craters, efficiency, flow acceleration

Abstract

The results are given of the film cooling experimental study on the flat plate with one array of inclined (α = 300) cylindrical holes in the craters. This data was obtained at 5 < x/d < 30. The relative spanwise pitch of holes t/d was 3.0, while the relative crater depth h/d was 0.8. The film injection parameter was ranged from 0.5 to 2.5. It was shown that laterally averaged film cooling efficiency with holes in craters exceeds the efficiency of the traditional scheme of inclined cylindrical holes. This excess is from 1.5 to 2 times on the initial region, while from 1.1 to 1.3 times beyond this area. Compared to the one-array configuration without craters the investigated film cooling scheme provides more uniform film coverage over the cooled surface. The flow acceleration in the range of 0,5·10-6 < К < 3,5·10-6 for the one array of holes reduces the film cooling efficiency up to 10% depending on the non-dimentional flow velocity. As a result of the experimental data summarizing, the power correlation was obtained describing the lateral averaged film cooling efficiency as a function of the relative main flow velocity for the zero pressure gradient and accelerating flow conditions.

Author Biographies

Артем Артемович Халатов, Institute of engineering thermophysics of NAS of Ukraine 2a Zhelyabov str., Kiev, Ukraine, 03057

Doctor of Technical Sciences, professor, associated member of NAS of Ukraine,

head of department

Department of high temperature thermogasdynamics

Игорь Иванович Борисов, Institute of engineering thermophysics of NAS of Ukraine 2a Zhelyabov str., Kiev, Ukraine, 03057

Candidat of Technical Sciences, leading scientist

Department of high temperature thermogasdynamics

Юрий Яковлевич Дашевский, Gas turbine research &production complex «Zorya»–«Mashproekt» Zhovtnevyy av., 42–a, Mykolaiv City, Ukraine, 54018

Candidat of Technical Sciences, head of sector

Department of turbines

Александр Сергеевич Коваленко, Institute of engineering thermophysics of NAS of Ukraine 2a Zhelyabov str., Kiev, Ukraine, 03057

Candidat of Technical Sciences, senior scientist

Department of high temperature thermogasdynamics

Сергей Владимирович Шевцов, Institute of engineering thermophysics of NAS of Ukraine 2a Zhelyabov str., Kiev, Ukraine, 03057

Candidat of Technical Sciences, leading scientist

Department of high temperature thermogasdynamics

References

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  12. Lutum, E., Wolfersdorf, J., Semmler, K., Dittmar, J., Weigand, B. (2001). An experimental investigation of fillm cooling on a convex surface subjected to favourable pressure gradient flow. Int. Journal of Heat and Mass Transfer, Vol. 44, 939–951.

Published

2013-06-19

How to Cite

Халатов, А. А., Борисов, И. И., Дашевский, Ю. Я., Коваленко, А. С., & Шевцов, С. В. (2013). Film cooling of a flat plate by one row of inclined holes located in craters at external flow acceleration. Eastern-European Journal of Enterprise Technologies, 3(12(63), 54–57. https://doi.org/10.15587/1729-4061.2013.14881

Issue

Section

Modern technologies in the gas-turbine