An Experimental Study of Mist/Air Film Cooling With Fan-Shaped Holes on an Extended Flat Plate—Part 1: Heat Transfer

Ragab, Reda; Wang, Ting

doi:10.1115/1.4037641

Cited by 16 publications

(3 citation statements)

References 33 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…5 for the same Tu and BR. It has been observed that from X/D = 3 to X/D = 15, Mc = 7% yields the highest laterally averaged cooling effectiveness, representing an optimal parametric choice for near injection hole cooling, as highlighted in several previous studies [18,19]. However, within the region between X/D = 15 to X/D = 40, the laterally averaged effectiveness of Mc = 7% is surpassed by Mc = 4%.…”

Section: Effect Of Mist Concentrationmentioning

confidence: 60%

Strategic Cooling Enhancement through Trench-Shaped Injection Holes - Two-Phase Numerical Study

Verma,

Mishra

2024

Proceedings of the 9th World Congress on Momentum, Heat and Mass Transfer

View full text Add to dashboard Cite

A two-phase numerical investigation on trench-shaped injection holes for film cooling is being conducted using Reynolds-averaged Navier-Stokes simulations to assess their practical effectiveness. The study is focusing on the cooling performance of a novel type of film holes, known as straight transverse trenches attached to a flat plate, using a mixture of water mist and air in the coolant fluid. The examination considers film cooling with varying turbulent intensities (3%, 10%, and 20%) and mist concentrations (4%, 7%, and 10%). The analysis involves adiabatic laterally averaged film cooling effectiveness parameters, with two blowing ratios ranging from 0.6 to 1.0. The findings indicate that trenched cooling holes exhibit a more uniform coolant distribution laterally at all positions, resulting in enhanced cooling performance, particularly at high blowing ratios.

show abstract

Section: Effect Of Mist Concentrationmentioning

confidence: 60%

Strategic Cooling Enhancement through Trench-Shaped Injection Holes - Two-Phase Numerical Study

Verma,

Mishra

2024

Proceedings of the 9th World Congress on Momentum, Heat and Mass Transfer

View full text Add to dashboard Cite

show abstract

“…They mentioned that the bending back of air-mist coolant stream towards the blade surface is crucial in keeping the mist droplets close to the surface and, thus, enhance cooling effectiveness. Later, Ragab and Wang (2018) extended the study to understand the mist-air film cooling with fan-shaped holes over an extended flat plate. They observed an increase in laterally averaged cooling effectiveness and also in the extended downstream region when compared to cylindrical cooling hole.…”

Section: Introductionmentioning

confidence: 99%

A numerical study of mist-air film cooling on a 3-D flat plate

M.V.V.

Surya²,

Singh³

et al. 2022

HFF

View full text Add to dashboard Cite

Purpose The purpose of this study is to explore the mist-air film cooling performance on a three-dimensional (3-D) flat plate. In mist-air film cooling technique, a small amount of water droplets is injected along with the coolant air. The objective is to study the influence of shape of the coolant hole and operating conditions on the cooling effectiveness. Design/methodology/approach In this study, 3-D numerical simulations are performed. To simulate the mist-air film cooling over a flat plate, air is considered as a continuous phase and mist is considered as a discrete phase. Turbulence in the flow is accounted using Reynolds averaged Navier–Stokes equation and is modeled using k–e model with enhanced wall treatment. Findings The results of this study show that, for cylindrical coolant hole, coolant with 5% mist concentration is not effective for mainstream temperatures above 600 K, whereas for fan-shaped hole, even 2% mist concentration has shown significant impact on cooling effectiveness for temperatures up to 1,000 K. For given mist-air coolant flow conditions, different trend in effectiveness is observed for cylindrical and fan-shaped coolant hole with respect to main stream temperature. Research limitations/implications This study is limited to a flat plate geometry with single coolant hole. Practical implications The motivation of this study comes from the requirement of high efficiency cooling techniques for cooling of gas turbine blades. This study aims to study the performance of mist-air film cooling at different geometric and operating conditions. Originality/value The originality of this study lies in studying the effect of parameters such as mist concentration, droplet size and blowing ratio on cooling performance, particularly at high mainstream temperatures. In addition, a systematic performance comparison is presented between the cylindrical and fan-shaped cooling hole geometries.

show abstract

“…The results showed that compared to the round hole, the oval hole reduces the strength of the main counter rotating vortex pair. Wang., 2018a, Ragab andWang., 2018b used infrared cameras and thermocouples to measure the temperature field and found that the newly incorporated fan-shaped film cooling hole had higher film cooling efficiency than cylindrical holes. Lee et al, 2021 experimentally investigated the effect of mainstream velocity on the optimization of a fan-shaped hole on a flat plate and found that the optimized hole showed a 49.3% improvement in the overall averaged film cooling effectiveness compared to the reference hole with DR 2.0 and M 2.0.…”

Section: Introductionmentioning

confidence: 99%

Research on the Hole Length Ratio of Fan-Shaped Holes in Flat Plate Film Cooling

2021

View full text Add to dashboard Cite

To study the influence of different hole length ratios on the flow structure and film cooling efficiency, a calculation model of fan-shaped hole was constructed and numerically studied. The effect of different hole length ratios on the cooling efficiency under different blowing ratios was compared and analyzed. The results showed that as the blowing ratio increases, the overall average efficiency of most of the hole length ratio cases first increases and then decreases. Only in the case with a cylindrical part length/total length ratio of 0.5 did the efficiency continue to increase. When the blowing ratio is small, the spanwise average efficiency of each hole length ratio case is closer, but the flow structure and efficiency distribution are quite different. For the medium blowing ratio, the overall average efficiency of the small hole length ratio case is higher, and the efficiency decreases as the hole length ratio increases. When the cylindrical part length/total length ratio is further increased to 1, the cooling efficiency region basically converges into a spanwise narrow region. For larger blowing ratio conditions, after 10D after the hole outlet, the case with a cylindrical part length/total length of 0.5 is more efficient.

show abstract

An Experimental Study of Mist/Air Film Cooling With Fan-Shaped Holes on an Extended Flat Plate—Part 1: Heat Transfer

Cited by 16 publications

References 33 publications

Strategic Cooling Enhancement through Trench-Shaped Injection Holes - Two-Phase Numerical Study

Strategic Cooling Enhancement through Trench-Shaped Injection Holes - Two-Phase Numerical Study

A numerical study of mist-air film cooling on a 3-D flat plate

Research on the Hole Length Ratio of Fan-Shaped Holes in Flat Plate Film Cooling

Contact Info

Product

Resources

About