Influences of a multi-cavity tip on the blade tip and the over tip casing aerothermal performance in a high pressure turbine cascade

Du, Kun; Li, Zhigang; Li, Jun; Sunden, Bengt

Influences of a multi-cavity tip on the blade tip and the over tip casing aerothermal performance in a high pressure turbine cascade

Mark

Du, Kun ^LU ; Li, Zhigang ; Li, Jun and Sunden, Bengt ^LU (2019) In Applied Thermal Engineering 147. p.347-360

Abstract: In modern gas turbine, the over tip leakage flow is inevitably generated in the tip gap of the first stage turbine blade due to the freestanding airfoil. In order to obtain a higher thermal efficiency, the turbine inlet temperature is gradually increased. Therefore, the over tip leakage flow induces significant aerodynamic losses and the blade tip and the over tip casing endure high level of thermal load. In the pursuit of a high-performance turbine engine, cavity tips are widely implemented in the turbine blade to reduce the over tip leakage flow and the thermal load on the blade tip and over tip casing. In the current study, the influences of the multi-cavity squealer tip on the blade tip and the over tip casing aerothermal... (More); In modern gas turbine, the over tip leakage flow is inevitably generated in the tip gap of the first stage turbine blade due to the freestanding airfoil. In order to obtain a higher thermal efficiency, the turbine inlet temperature is gradually increased. Therefore, the over tip leakage flow induces significant aerodynamic losses and the blade tip and the over tip casing endure high level of thermal load. In the pursuit of a high-performance turbine engine, cavity tips are widely implemented in the turbine blade to reduce the over tip leakage flow and the thermal load on the blade tip and over tip casing. In the current study, the influences of the multi-cavity squealer tip on the blade tip and the over tip casing aerothermal performance were numerically investigated. Three-dimensional (3D) Reynolds-Averaged Navier-Stokes (RANS) equations and standard k-ω turbulence model were solved to conduct the simulations. The results indicate that the flat tip attains the largest thermal load on the blade tip, over-tip casing and induces the largest total pressure loss. However, the case with a single tip cavity (1CST) achieves the smallest total pressure loss and heat transfer coefficient on the over-tip casing, which are 7.6% and 19.6% lower than the flat tip, respectively. The case with a multi-cavity tip obtains a decreasing heat transfer coefficient on the blade tip. The case with five tip cavities (5CST) achieves the smallest heat transfer coefficient on the blade tip among all simulated cases, which is decreased by 17.5% relative to the flat tip.
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Please use this url to cite or link to this publication: https://lup.lub.lu.se/record/b9229777-7f85-4abb-ad55-dc876e2f76c7

author

Du, Kun ^LU ; Li, Zhigang ; Li, Jun and Sunden, Bengt ^LU

organization

Heat Transfer

publishing date

2019

type

Contribution to journal

publication status

published

subject

Energy Engineering

keywords

Blade tip, Gas turbine, Multi-cavity, Numerical simulations

in

Applied Thermal Engineering

volume

147

pages

14 pages

publisher

Elsevier

external identifiers

scopus:85055335633

ISSN

1359-4311

DOI

10.1016/j.applthermaleng.2018.10.093

language

English

LU publication?

yes

id

b9229777-7f85-4abb-ad55-dc876e2f76c7

date added to LUP

2018-11-14 08:13:17

date last changed

2022-04-25 18:36:18

@article{b9229777-7f85-4abb-ad55-dc876e2f76c7,
  abstract     = {{<p>In modern gas turbine, the over tip leakage flow is inevitably generated in the tip gap of the first stage turbine blade due to the freestanding airfoil. In order to obtain a higher thermal efficiency, the turbine inlet temperature is gradually increased. Therefore, the over tip leakage flow induces significant aerodynamic losses and the blade tip and the over tip casing endure high level of thermal load. In the pursuit of a high-performance turbine engine, cavity tips are widely implemented in the turbine blade to reduce the over tip leakage flow and the thermal load on the blade tip and over tip casing. In the current study, the influences of the multi-cavity squealer tip on the blade tip and the over tip casing aerothermal performance were numerically investigated. Three-dimensional (3D) Reynolds-Averaged Navier-Stokes (RANS) equations and standard k-ω turbulence model were solved to conduct the simulations. The results indicate that the flat tip attains the largest thermal load on the blade tip, over-tip casing and induces the largest total pressure loss. However, the case with a single tip cavity (1CST) achieves the smallest total pressure loss and heat transfer coefficient on the over-tip casing, which are 7.6% and 19.6% lower than the flat tip, respectively. The case with a multi-cavity tip obtains a decreasing heat transfer coefficient on the blade tip. The case with five tip cavities (5CST) achieves the smallest heat transfer coefficient on the blade tip among all simulated cases, which is decreased by 17.5% relative to the flat tip.</p>}},
  author       = {{Du, Kun and Li, Zhigang and Li, Jun and Sunden, Bengt}},
  issn         = {{1359-4311}},
  keywords     = {{Blade tip; Gas turbine; Multi-cavity; Numerical simulations}},
  language     = {{eng}},
  pages        = {{347--360}},
  publisher    = {{Elsevier}},
  series       = {{Applied Thermal Engineering}},
  title        = {{Influences of a multi-cavity tip on the blade tip and the over tip casing aerothermal performance in a high pressure turbine cascade}},
  url          = {{http://dx.doi.org/10.1016/j.applthermaleng.2018.10.093}},
  doi          = {{10.1016/j.applthermaleng.2018.10.093}},
  volume       = {{147}},
  year         = {{2019}},
}

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Influences of a multi-cavity tip on the blade tip and the over tip casing aerothermal performance in a high pressure turbine cascade