Research on a high-precision real-time improvement method for aero-engine component-level model

IF 0.7 4区 工程技术 Q4 ENGINEERING, AEROSPACE
Qiangang Zheng, Liangliang Li, Haibo Zhang, Jiajie Chen
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引用次数: 0

Abstract

Abstract In order to improve the real-time performance of the aero-engine Component-Level Model (CLM) while ensuring accuracy, a method for the Calculation of Thermodynamic Parameters of Working Fluids (CTPWF) based on a Neural Network and Newton Raphson (NN-NR) is proposed. In this method, the enthalpy or entropy under different fuel-air ratio and humidity conditions is mapped to temperature by a neural network, and the mapping output is used as the initial solution of Newton Raphson (NR) iteration. Then, a high-precision solution can be obtained through a few iterations, which avoids the shortcoming that the traditional method uses a fixed initial solution that leads to too many iterative steps. This effectively reduces the number of iterative steps and improves the calculation efficiency. This method is applied to the aero-thermodynamic calculation of each component of an engine CLM, which improves the accuracy and real-time performance of the CLM. The simulation results show that, compared to the traditional method, the proposed method improves the accuracy of the CTPWF and can reduces the single aero-thermodynamic calculation time by 25 % when humidity is not considered and by 47 % when humidity is considered. This effectively improves the real-time performance of the CLM.
航空发动机零部件级模型的高精度实时改进方法研究
摘要为了在保证精度的同时提高航空发动机部件级模型(CLM)的实时性,提出了一种基于神经网络和牛顿-拉夫逊(NN-NR)的工作流体热力学参数计算方法。在该方法中,通过神经网络将不同燃料空气比和湿度条件下的焓或熵映射到温度,并将映射输出用作Newton-Raphson(NR)迭代的初始解。然后,通过几次迭代可以获得高精度的解,避免了传统方法使用固定初始解导致迭代步骤过多的缺点。这有效地减少了迭代步骤的数量并提高了计算效率。将该方法应用于发动机CLM各部件的气动热力学计算,提高了CLM的精度和实时性。仿真结果表明,与传统方法相比,该方法提高了CTPWF的精度,并可将单个气动热力学计算时间减少25 % 当不考虑湿度时 % 当考虑湿度时。这有效地提高了CLM的实时性能。
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来源期刊
International Journal of Turbo & Jet-Engines
International Journal of Turbo & Jet-Engines 工程技术-工程:宇航
CiteScore
1.90
自引率
11.10%
发文量
36
审稿时长
6 months
期刊介绍: The Main aim and scope of this Journal is to help improve each separate components R&D and superimpose separated results to get integrated systems by striving to reach the overall advanced design and benefits by integrating: (a) Physics, Aero, and Stealth Thermodynamics in simulations by flying unmanned or manned prototypes supported by integrated Computer Simulations based on: (b) Component R&D of: (i) Turbo and Jet-Engines, (ii) Airframe, (iii) Helmet-Aiming-Systems and Ammunition based on: (c) Anticipated New Programs Missions based on (d) IMPROVED RELIABILITY, DURABILITY, ECONOMICS, TACTICS, STRATEGIES and EDUCATION in both the civil and military domains of Turbo and Jet Engines. The International Journal of Turbo & Jet Engines is devoted to cutting edge research in theory and design of propagation of jet aircraft. It serves as an international publication organ for new ideas, insights and results from industry and academic research on thermodynamics, combustion, behavior of related materials at high temperatures, turbine and engine design, thrust vectoring and flight control as well as energy and environmental issues.
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