Investigation on Multi-Row Film Cooling Calculation Based on the Source Term Model

Siqi Sun; Bo Kong; Qitai Eri; Yong Wang

doi:10.3233/ATDE260036

Investigation on Multi-Row Film Cooling Calculation Based on the Source Term Model

Siqi Sun
, Bo Kong^*
, Qitai Eri
, Yong Wang

^*Corresponding author for this work

School of Energy and Power Engineering

Beihang University

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

Film cooling technology is an effective method for reducing the wall temperature of high-temperature components in aero-engines and is one of the primary thermal protection measures. Conventional film cooling calculation methods heavily rely on highly refined mesh generation, which complicates the modeling of film cooling hole structures. To simplify the complex mesh requirements, this study proposes a source term model-based film cooling calculation method. Based on flat-plate film cooling experimental data, a neural network-based deep learning approach was employed to establish the relationship between the discharge coefficient and operating conditions as well as film cooling hole parameters. The effects of different operating conditions and film cooling hole parameters on the discharge coefficient were analyzed. Furthermore, the wall temperature distributions, pressure distributions along the flow path, and temperature values at multiple points obtained from the source term method were compared with experimental results and full-size numerical simulation results. The findings demonstrate that the discharge coefficients derived from neural network training facilitate accurate calculation of source term parameters. The source term model can effectively replace the real film cooling hole model for numerical simulations of film cooling structures, achieving high computational accuracy.

Original language	English
Title of host publication	Moving Integrated Product Development to Service Clouds in the Global Economy - Proceedings of the 21st ISPE Inc. International Conference on Concurrent Engineering, CE 2014
Editors	Xuelin Lei
Publisher	IOS Press BV
Pages	214-226
Number of pages	13
ISBN (Electronic)	9781643686479
DOIs	https://doi.org/10.3233/ATDE260036
State	Published - 3 Mar 2026
Event	16th International Conference of Mechanical and Aerospace Engineering, ICMAE 2025 - Rome, Italy Duration: 15 Jul 2025 → 18 Jul 2025

Publication series

Name	Advances in Transdisciplinary Engineering
Volume	87
ISSN (Print)	2352-751X
ISSN (Electronic)	2352-7528

Conference

Conference	16th International Conference of Mechanical and Aerospace Engineering, ICMAE 2025
Country/Territory	Italy
City	Rome
Period	15/07/25 → 18/07/25

Keywords

film cooling
neural network
source term model
wall temperature

Access to Document

10.3233/ATDE260036

Cite this

Sun, S., Kong, B., Eri, Q., & Wang, Y. (2026). Investigation on Multi-Row Film Cooling Calculation Based on the Source Term Model. In X. Lei (Ed.), Moving Integrated Product Development to Service Clouds in the Global Economy - Proceedings of the 21st ISPE Inc. International Conference on Concurrent Engineering, CE 2014 (pp. 214-226). (Advances in Transdisciplinary Engineering; Vol. 87). IOS Press BV. https://doi.org/10.3233/ATDE260036

Sun, Siqi ; Kong, Bo ; Eri, Qitai et al. / Investigation on Multi-Row Film Cooling Calculation Based on the Source Term Model. Moving Integrated Product Development to Service Clouds in the Global Economy - Proceedings of the 21st ISPE Inc. International Conference on Concurrent Engineering, CE 2014. editor / Xuelin Lei. IOS Press BV, 2026. pp. 214-226 (Advances in Transdisciplinary Engineering).

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title = "Investigation on Multi-Row Film Cooling Calculation Based on the Source Term Model",

abstract = "Film cooling technology is an effective method for reducing the wall temperature of high-temperature components in aero-engines and is one of the primary thermal protection measures. Conventional film cooling calculation methods heavily rely on highly refined mesh generation, which complicates the modeling of film cooling hole structures. To simplify the complex mesh requirements, this study proposes a source term model-based film cooling calculation method. Based on flat-plate film cooling experimental data, a neural network-based deep learning approach was employed to establish the relationship between the discharge coefficient and operating conditions as well as film cooling hole parameters. The effects of different operating conditions and film cooling hole parameters on the discharge coefficient were analyzed. Furthermore, the wall temperature distributions, pressure distributions along the flow path, and temperature values at multiple points obtained from the source term method were compared with experimental results and full-size numerical simulation results. The findings demonstrate that the discharge coefficients derived from neural network training facilitate accurate calculation of source term parameters. The source term model can effectively replace the real film cooling hole model for numerical simulations of film cooling structures, achieving high computational accuracy.",

keywords = "film cooling, neural network, source term model, wall temperature",

author = "Siqi Sun and Bo Kong and Qitai Eri and Yong Wang",

note = "Publisher Copyright: {\textcopyright} 2026 The Authors.; 16th International Conference of Mechanical and Aerospace Engineering, ICMAE 2025 ; Conference date: 15-07-2025 Through 18-07-2025",

year = "2026",

month = mar,

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doi = "10.3233/ATDE260036",

language = "英语",

series = "Advances in Transdisciplinary Engineering",

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Sun, S, Kong, B , Eri, Q & Wang, Y 2026, Investigation on Multi-Row Film Cooling Calculation Based on the Source Term Model. in X Lei (ed.), Moving Integrated Product Development to Service Clouds in the Global Economy - Proceedings of the 21st ISPE Inc. International Conference on Concurrent Engineering, CE 2014. Advances in Transdisciplinary Engineering, vol. 87, IOS Press BV, pp. 214-226, 16th International Conference of Mechanical and Aerospace Engineering, ICMAE 2025, Rome, Italy, 15/07/25. https://doi.org/10.3233/ATDE260036

Investigation on Multi-Row Film Cooling Calculation Based on the Source Term Model. / Sun, Siqi; Kong, Bo ; Eri, Qitai et al.
Moving Integrated Product Development to Service Clouds in the Global Economy - Proceedings of the 21st ISPE Inc. International Conference on Concurrent Engineering, CE 2014. ed. / Xuelin Lei. IOS Press BV, 2026. p. 214-226 (Advances in Transdisciplinary Engineering; Vol. 87).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - Investigation on Multi-Row Film Cooling Calculation Based on the Source Term Model

AU - Sun, Siqi

AU - Kong, Bo

AU - Eri, Qitai

AU - Wang, Yong

PY - 2026/3/3

Y1 - 2026/3/3

N2 - Film cooling technology is an effective method for reducing the wall temperature of high-temperature components in aero-engines and is one of the primary thermal protection measures. Conventional film cooling calculation methods heavily rely on highly refined mesh generation, which complicates the modeling of film cooling hole structures. To simplify the complex mesh requirements, this study proposes a source term model-based film cooling calculation method. Based on flat-plate film cooling experimental data, a neural network-based deep learning approach was employed to establish the relationship between the discharge coefficient and operating conditions as well as film cooling hole parameters. The effects of different operating conditions and film cooling hole parameters on the discharge coefficient were analyzed. Furthermore, the wall temperature distributions, pressure distributions along the flow path, and temperature values at multiple points obtained from the source term method were compared with experimental results and full-size numerical simulation results. The findings demonstrate that the discharge coefficients derived from neural network training facilitate accurate calculation of source term parameters. The source term model can effectively replace the real film cooling hole model for numerical simulations of film cooling structures, achieving high computational accuracy.

AB - Film cooling technology is an effective method for reducing the wall temperature of high-temperature components in aero-engines and is one of the primary thermal protection measures. Conventional film cooling calculation methods heavily rely on highly refined mesh generation, which complicates the modeling of film cooling hole structures. To simplify the complex mesh requirements, this study proposes a source term model-based film cooling calculation method. Based on flat-plate film cooling experimental data, a neural network-based deep learning approach was employed to establish the relationship between the discharge coefficient and operating conditions as well as film cooling hole parameters. The effects of different operating conditions and film cooling hole parameters on the discharge coefficient were analyzed. Furthermore, the wall temperature distributions, pressure distributions along the flow path, and temperature values at multiple points obtained from the source term method were compared with experimental results and full-size numerical simulation results. The findings demonstrate that the discharge coefficients derived from neural network training facilitate accurate calculation of source term parameters. The source term model can effectively replace the real film cooling hole model for numerical simulations of film cooling structures, achieving high computational accuracy.

KW - film cooling

KW - neural network

KW - source term model

KW - wall temperature

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Y2 - 15 July 2025 through 18 July 2025

ER -

Sun S, Kong B , Eri Q, Wang Y. Investigation on Multi-Row Film Cooling Calculation Based on the Source Term Model. In Lei X, editor, Moving Integrated Product Development to Service Clouds in the Global Economy - Proceedings of the 21st ISPE Inc. International Conference on Concurrent Engineering, CE 2014. IOS Press BV. 2026. p. 214-226. (Advances in Transdisciplinary Engineering). doi: 10.3233/ATDE260036

Investigation on Multi-Row Film Cooling Calculation Based on the Source Term Model

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