A novel framework for liquid propellant engine’s cooling system design by sensitivity analysis based on RSM and multi-objective optimization using PSO

One of the challenges of combustion chamber and nozzle design in a Liquid Propellant Engine (LPE) is to predict the behavior and performance of the cooling system. Therefore, while designing, the optimization of the cooling system is always of great importance. This paper presents the multi-objective optimization of the LPE’s cooling system. To this end, a novel framework has been developed, resulting from the application of the Response Surface Method (RSM) and the correlation coefficients matrix, sensitivity analysis and the The Particle Swarm Optimization (PSO). based on this method, the input variables, constraints, objective functions, and their surfaces were identified. In terms of multi-optimization algorithms, RSM and PSO are utilized to get global optimum. In conclusion, the methodology capability is to optimize the LPE’s cooling system, 6 percentage increase in total heat transfer and 7 bar decrease cooling system pressure loss, which resulted in a 1.2-seconds increase in the specific impulse of the engine.     

基于拓扑优化的航空发动机滑油箱支架设计

支架是航空发动机滑油箱组件中的重要部件,用于连接和固定滑油箱组件中的箍带.但现有支架设计会引起与之相连的箍带承受偏心拉力,导致结构应力水平偏高进而发生疲劳破坏.本文提出了一种考虑结构局部刚度的拓扑优化方法,能够在提升支架整体刚度的同时兼顾局部刚度,使支架的刚度分布更加合理,进而显著降低与之相连的箍带的应力水平.利用该优...     

整级环境下涡轮叶片型面加工几何偏差影响的不确定性分析

加工等过程中产生的几何偏差会导致涡轮叶片气动性能及工作状态发生显著变化,对该影响的准确评估与合理分析具有重要意义.本文提出了一种考虑三维型面几何偏差对气动性能影响的不确定性计算分析方法,包括随机叶型几何建模、不确定性量化计算和敏感性分析等,并结合某一单级高压涡轮进行分析.基于随机过程理论和主成分分析法,参考现有叶片加工...     

射频干扰对InSAR干涉处理的影响分析

窄带干扰是低频段InSAR系统面临的主要射频干扰之一,它的存在会对干涉相位产生严重影响,进而导致高程反演误差。本文推导了窄带干扰影响下的InSAR干涉相位的解析表达式,给出了干涉相位对窄带干扰各参数的敏感度方程,仿真分析了窄带干扰对P波段InSAR系统干涉处理的影响。结果表明,窄带干扰经过成像后其幅度调制函数近似为方位时间的sinc函数,在SAR图像中表现为沿距离向的干扰条带。干涉相位对窄带干扰信号的功率较敏感,对其频率较不敏感,干涉相位和高程反演误差随着干信比的增加而增加。     

考虑跟踪制导的小天体着陆轨迹闭环优化方法

针对小天体着陆环境存在参数不确定性及初始状态偏差的特点,提出一种小天体着陆闭环优化方法,实现在节省燃料消耗的同时降低对参数的敏感度。首先,建立小天体着陆动力学模型,分析了燃料最优着陆问题;然后,采用线性二次型调节器设计了反馈制导律,推导闭环敏感度矩阵方程,构造燃料消耗和敏感度加权的性能指标,进而能够通过优化降低小天体着陆过程的敏感度。仿真结果表明,该闭环优化方法能有效降低对参数不确定性和初始状态偏差的敏感度,最终达到提高小天体着陆位置和速度精度的目标。     

单航过单平台InSAR基线模型的敏感性分析

从单航过单平台InSAR系统对其自身基线的高精度需求出发,给出了光学测量方案下的基线模型,并针对模型中的各因素及其误差来源,进行了模型的敏感性分析,阐明了测量元素与位置修正矢量的基线矢量的误差传递关系,然后根据误差传递关系找出测量系统的优化安装部位。通过解析推导得出各类误差源在不同条件下对基线精度影响的理论结果,由仿真分析给出了不同安装部位的误差传递系数。通过敏感性分析可由测量环境的输入条件直接获得基线的误差量级,其结果可作为指导测量系统方案设计与精度分配的参考依据。     

A method of multi-objective reliability tolerance design for electronic circuits

Tolerance design plays an important role in reliability design for electronic circuits. The traditional method only focuses on the consistency of output response. It is not able to meet the needs of increasing development of electronic products. This paper researches the state of related fields and proposes a method of multi-objective reliability tolerance design. The characteristics of output response and operating stresses on critical components are both defined as design objectives. Critical components and their operating stresses are determined by failure mode and effect analysis (FMEA) and fault tree analysis (FTA). Sensitivity analysis is carried out to determine sensitive parameters that affect the design objectives significantly. Monte Carlo and worst-case analysis are utilized to explore the tolerance levels of sensitive parameters. Design of experiment and regression analysis are applied in this method. The optimal tolerance levels are selected in accord with a quality-cost model to improve consistency of output response and reduce failure rates of critical components synchronously. The application in light-emitting diode (LED) drivers indicates details and potential. It shows that the proposed method provides a more effective way to improve performance and reliability of electronic circuits.     

利用反射式衍射光栅进行瞬态应变测量

介绍了利用反射式衍射光栅进行瞬态应变测量的方法,在一维细长杆中,通过测量杆未端的绝对速度,就可以算出动态应变和应变灵敏度系数K,文章对该方法进行了理论计算和实验结果分析,给出了结论和进一步研究方向。     

Design of nanofluid-cooled heat sink using topology optimization

The paper presented topology optimization of 2D and 3D Nanofluid-Cooled Heat Sink (NCHS). The flow and heat transfer problem in the NCHS was treated as a single-phase nanofluid based convective heat transfer model. The temperature-dependent fluid properties were taken into account in the model due to the strong temperature-dependent features of nanofluids. An average temperature minimum problem was studied subject to the fluid area and energy dissipation constraints by using the density method. In the method, the design variable is updated according to the gradient information obtained by an adjoint based sensitivity analysis process. The effects of the energy dissipation constraint, temperature-dependent fluid properties and nanofluid characteristics on optimal configurations of NCHS were numerically investigated with following conclusions. Firstly, branched flow channels in the optimal configuration increased with the rise of the allowed energy dissipation. Secondly, temperature-dependent fluid properties were significant for obtaining the appropriate optimal results with best cooling performance. Thirdly, heat transfer performances of optimal configurations were enhanced by reducing the nanoparticle diameter or increasing the nanoparticle volume fraction. Fourthly, the optimal configuration for nanofluid had better cooling performance than that for its base fluid.     

Sensitivity analysis of flowfield modeling parameters upon the flow structure and aerodynamics of an opposing jet over a hypersonic blunt body

Implementation of an opposing jet in design of a hypersonic blunt body significantly modifies the external flowfield and yields a considerable reduction in the aerodynamic drag. This study aims to investigate the effects of flowfield modeling parameters of injection and freestream on the flow structure and aerodynamics of a blunt body with an opposing jet in hypersonic flow.Reynolds-Averaged Navier-Stokes(RANS) equations with a Shear Stress Transport(SST)turbulence model are employed to simulate...