Experimental Analysis of the Heat Transfer Variations Within an Internal Passage of a Typical Gas Turbine Blade Using Varied Internal Geometries

Hahn, Todd; Deakins, Bryant; Buechler, Andrew; Kumar, Sourabh; Amano, Ryoichi S.

doi:10.1115/detc2012-70686

Cited by 3 publications

(1 citation statement)

References 0 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In the past decades, scholars have conducted numerous studies on channel internal cooling. Hahn et al [1] analysed the heat transfer rate of varied geometries of rip turbulators within internal cooling channels of gas turbine blades experimentally. The results showed that the highest heat transfer performance occurs in the shape of the 60-degree staggered arrow away from the inlet and outlet.…”

Section: Introductionmentioning

confidence: 99%

Generative Design of Internal Cooling Channels for Gas Turbine Blades

Wang¹,

Yu²,

Lu³

et al. 2022

Proceedings of Global Power &Amp; Propulsion Society

View full text Add to dashboard Cite

Conventional cooling channels inside air-cooled turbine blades were mainly constructed by regular geometric features such as pin-fins, ribs or dimples. The heat transfer potential of such features were already well exploited by the literature in the past few decades, and the cooling performance of turbine blades has reached a bottle neck. Instead of manually crafting regular geometry shapes and making combinations, a novel concept arising in recent years advocated to generate complicated geometries by rules, which was named generative design. This study proposed a geometry generation method based on bionic rules and partial differential equations. The concept was inspired by the self-organization phenomenon of natural objects. Heat transfer evaluation was conducted on multiple geometries generated in different domains, with different length scale and with different equation parameters. The results indicated a wide range of heat transfer performance that generatively designed cooling channels could provide. Geometries with low porosity or high connectivity of the solid tended to have better heat transfer performance. Complex geometries were generated successfully under the control of the initial value of the phase filed. This method was expected to produce new possibility for enhancing cooling performance of turbine blades.

show abstract

Section: Introductionmentioning

confidence: 99%

Generative Design of Internal Cooling Channels for Gas Turbine Blades

Wang¹,

Yu²,

Lu³

et al. 2022

Proceedings of Global Power &Amp; Propulsion Society

View full text Add to dashboard Cite

show abstract

Exploring the Effects of Guide Vane on Dimpled Cooling Channel of Gas Turbine Blade

Nourin

Blum

Amano

2022

Journal of Energy Resources Technology

View full text Add to dashboard Cite

The purpose of the current study is to find out the heat transfer and pressure drop phenomena of the cooling channel with dimples and guide vane and compare the results with the no guide vane dimpled cooling channel. The first leg of the cooling channel is 490mm, and the second leg is 460 mm. The two legs relate to the 180 deg turn region. The guide vane was inserted at the bend region of the dimpled cooling channel. The study was conducted with two different guide vanes geometry at two different orientations, i.e., U-guide vane with protrusion and depression orientation and Curve -guide vane with protrusion and depression orientations both experimentally and numerically. The numerical study was performed with the large eddy simulation method. The result shows that both for stationary and rotational motion, the U-guide vane with depression experiences the highest thermal performance. The friction factor is comparatively higher for Curve – guide vane with protrusion under stationary motion. However, under rotation, the Curve- protrusion guide encounters the highest friction factor, which is higher compared to the no-guide vane cooling channel.

show abstract

Magnetic Resonance Velocimetry Measurements of Internal Blade Cooling Flow and Computational Fluid Dynamic Validation by Data Matching With the Experimental Data

Wüstenhagen

Domnick²,

John

et al. 2023

Journal of Thermal Science and Engineering Applications

View full text Add to dashboard Cite

The optimal Reynolds-Averaged-Navier Stokes (RANS) turbulence model to be used in a Computational Fluid Dynamics (CFD) simulation varies depending on the application. Conventionally, the model is selected from benchmark tests and experience, but its performance is difficult to predict. For this reason, this study presents a cost-effective CFD validation routine, which uses three-dimensional experimental velocity data obtained in replicas of the specific flow system. Magnetic Resonance Velocimetry (MRV) is used as the measurement technique. Since the objective is only the validation of the turbulence model, the experiment and the simulation are performed with simplified flow conditions, hence, stationary iso-thermal iso-volumetric flow without inertial forces. The routine applies a data matching routine to align the two three-dimensional data sets before they are interpolated on a common grid. Various error metrics are presented, which provide the degree of the CFD modelling error and indicate its source. For demonstration, the validation routine is used to evaluate RANS-CFD results of a three-pass internal cooling system of a high-pressure turbine airfoil used in a small industrial gas turbine. The simulations are performed with the eddy-viscosity based turbulence model k-w SST and the Reynolds-Stress SSG, and BSL-EARSM turbulence models. The results indicate strong local errors in the examined turbulence models. None of the models performed well enough, underlining that every RANS-CFD application needs to be validated.

show abstract

Experimental Analysis of the Heat Transfer Variations Within an Internal Passage of a Typical Gas Turbine Blade Using Varied Internal Geometries

Cited by 3 publications

References 0 publications

Generative Design of Internal Cooling Channels for Gas Turbine Blades

Generative Design of Internal Cooling Channels for Gas Turbine Blades

Exploring the Effects of Guide Vane on Dimpled Cooling Channel of Gas Turbine Blade

Magnetic Resonance Velocimetry Measurements of Internal Blade Cooling Flow and Computational Fluid Dynamic Validation by Data Matching With the Experimental Data

Contact Info

Product

Resources

About