Research on performance seeking control of turbofan engine in minimum hot spot temperature mode-Reference-Cited by-同舟云学术

Research on performance seeking control of turbofan engine in minimum hot spot temperature mode

Published:2024-06-17 Issue: Volume: Page:
ISSN:0334-0082
Container-title:International Journal of Turbo & Jet-Engines
language:en
Short-container-title:

Author:

Liu Yabing¹²,Zhang Hongwei³,Ma Bei²,Li Liangliang¹,Hu Chenxu²,Zheng Qiangang¹,Zhang Haibo¹

Affiliation:

1. 47854 College of Energy and Power Engineering, Nanjing University of Aeronautics and Astronautics , Nanjing , 210016 , China

2. 47854 AECC Aero Engine Control System Institute , Wuxi , 214063 , China

3. AECC Xi’an Engine Control Technology Co Ltd , Xi’an , 710077 , China

Abstract

Abstract The uneven temperature distribution at the combustion chamber outlet seriously affects the working life of the engine. In order to reduce the heat spot temperature at the combustion chamber outlet, a performance optimization control method of the engine minimum heat spot temperature pattern is proposed. Firstly, based on CFD method, the temperature distribution characteristics of combustion chamber outlet under different working conditions were obtained, and a component-level model of turbofan engine was established to characterize the heat spot temperature at combustion chamber outlet. Secondly, the high precision and high real-time engine on-board model is established by deep neural network. Compared with the component-level model, the average relative error of each performance parameter is less than 0.3 %, and the real-time performance is improved by 12 times. Finally, based on the feasible sequential quadratic programming algorithm, the performance optimization control of the minimum hot spot temperature model in the typical flight envelope is simulated and verified. The simulation results show that under the condition of ensuring the safe and stable operation of the engine and constant thrust, the heat spot temperature at the combustion chamber outlet decreases by 21 K maximum. Compared with the conventional minimum turbine front temperature optimization mode, the minimum heat spot temperature mode significantly reduces the heat spot temperature at the combustion chamber outlet.

Funder

Aero Engine Corporation of China industry-university-research cooperation project

Fund of Prospective Layout of Scientific Research for NUAA

Publisher

Walter de Gruyter GmbH

Link

https://www.degruyter.com/document/doi/10.1515/tjj-2024-0022/pdf

Reference43 articles.

1. Lin, H, Shang, S, Cheng, M, Ma, H, Chang, F. Engineering application and development analysis of high fuel-air ratio combustion technology. Aeroengine 2021;47:72–81.

2. Arthur, HL, Dilip, RB. Gas turbine engine combustion. Beijing, China: Aviation Industry Press; 2016.

3. Zhou, J, Wan, P, Han, S, Mao, J, Bi, S, Cai, K. Very-large Eddy simulation of turbulent flow and heat transfer for coupled combustor-turbine components. J Propuls Technol 2022;43:11.

4. Xie, J, Liu, Z, Zhang, X, Zhu, C, Zhao, W. Design of an experimental apparatus for turbine cascade inlet hot streak migration and influences research. Gas Turb Exp Res 2018;31:8.

5. Barringer, MD, Thole, KA, Polanka, MD. Experimental evaluation of an inlet profile generator for high-pressure turbine tests. J Turbomach 2007;129:382–93. https://doi.org/10.1115/1.2436897.