Optimization Research on the Heat Transfer Capacity of an Aircraft Fuel Thermal Management System

IF 0.1 4区工程技术 Q4 ENGINEERING, AEROSPACE

Aerospace America Pub Date : 2023-08-20 DOI:10.3390/aerospace10080730

Qidong Zhang, G. Lin, Jinghui Guo, Haichuan Jin, Qiming Zhang

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Abstract

The thermal management system (TMS) for aircraft fuel is a critical component of integrated TMSs in aircraft. As such, its optimal design is necessary to ensure the efficient completion of flight missions. This study presents the model building of a numerical simulation model for the fuel TMS, with the objective of minimizing fuel return flow. Sensitivity analysis was performed using variance analysis. The genetic algorithm was utilized for the optimization of the model building, taking into consideration the system’s geometric structure and performance parameters, which include the pipe length, the ram air-fuel HX’s efficiency, and the ram air’s volume flow rate in the ram air cooling subsystem, as design variables. The optimization solution for system design variables yielded a design scheme with the highest working efficiency for the fuel TMS. In this paper, the genetic algorithm in AMEsim software is adopted, which can also effectively optimize the design parameters and achieve the optimization objective. Compared with the original TMS structure, the heat dissipation capacity of the fuel TMS is improved and reduced the return fuel flow by 67.4% after the optimization of system structure parameters.

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某型飞机燃油热管理系统传热能力优化研究

飞机燃油热管理系统是飞机综合热管理系统的重要组成部分。因此，其优化设计是保证高效完成飞行任务的必要条件。本文以燃油回流最小为目标，建立了燃油TMS的数值模拟模型。采用方差分析进行敏感性分析。考虑系统的几何结构和性能参数，包括管道长度、冲压空气-燃料HX效率和冲压空气冷却子系统中的冲压空气体积流量作为设计变量，利用遗传算法对模型构建进行优化。通过对系统设计变量的优化求解，得出了燃油TMS工作效率最高的设计方案。本文采用AMEsim软件中的遗传算法，也能有效地优化设计参数，实现优化目标。与原TMS结构相比，经过系统结构参数优化后，燃油TMS的散热能力得到了提高，回程燃油流量减少了67.4%。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Aerospace America 工程技术-工程：宇航

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0.00%

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审稿时长

4-8 weeks