摩托车发动机机加柔性生产线工艺设计

技术改造实施成功与否,很大程度取决于该项目的工艺设计水平。本文从柔性生产线工艺设计依据、指导思想、主要设计内容,以及生产线总体技术水平和经验教训等方面,较详细地介绍了摩托车发动机机加柔性生产线工艺设计的全过程。     

基于PDCA的EWIS设计质量提升研究与应用

为了全面提升军用飞机线束及线束敷设设计质量,从设计源头根本性改善外场线路问题,从系统设计的角度出发,开展了EWIS (电气线路互联系统)设计质量控制的新流程、新方法和新技术的研究和应用。根据设计质量问题和改进需求分析结果,提出了基于PDCA (质量环)的质量控制方法,并将其应用到实践中,完善了EWIS技术文件体系,形成了EWIS精细化设计及检查验证流程,提高了设计要求的提出、实现、验证和持续完善能力,在此基础上优化了对重量特性的控制过程,极大提高了设计质量和效率,对提升飞机EWIS设计质量具有参考意义。     

卫星遥感农业监测系统中实例检索算法研究

针对智慧农业中需求获取手段、表达方法等导致智能设计算法复杂度高、可用性低等问题，将卫星遥感技术和网络技术结合实现农作物及其生长环境参数的实时监测，以优化播种机设计的需求特征，并以此为基础，提出基于混合相似度的实例检索模型。在该模型中，设计了多级实例库结构，并以特征间距离相似度、特征间可拓关联度、特征间可拓距测度为组成要素，构造多级混合相似度的层次结构与计算方法，进行多级实例检索。将其应用到铲式播种机的数字化设计系统中，可获得与目标实例最相似的实例。实验结果表明，在实例的特征值数据类型多样化的情况下，此算法能够有效地检索出合适的历史实例，提高检索结果的可用性。     

基于WPF的民机驾驶舱人机接口快速原型技术

新一代Windows呈现基础(WPF)技术以其丰富的界面表现力和功能扩展能力被广泛应用于图形处理和界面设计上。WPF技术应用于民机驾驶舱人机接口快速原型的开发过程中,将界面与逻辑的开发完全分离,提升开发效率,增强模型可复用性。基于此流程创建的人机接口快速原型可用于显示系统研发过程中的早期设计阶段,确认需求的合理性,优化人机接口设计,减少后期显示系统软件研制过程中的更改,缩短开发周期,具有重要的工程应用价值。     

仅用作航空器追踪的北斗机载设备适航要求分析

北斗卫星导航系统（简称北斗）在民用航空器中安装应用的前提是明确和符合北斗机载设备的适航要求。但由于全球定位系统（GPS）与北斗在星座结构、信号体制及功能上的不同，导致目前国际上全球卫星导航系统（GNSS）相关适航标准不适用于北斗设备。标准的缺失严重制约北斗民航产业发展，急需进行自主研究与制定。针对北斗在民用航空器中应用第一阶段的功能及场景，即仅用作航空器追踪，分析当前可参考标准的适用性，明确适航要求的制订策略及框架，综合考虑适航安全性、民航对北斗机载设备的紧迫需求，未来机载设备的发展方向，以及当前工业水平，提出一套仅用作航空器追踪的北斗机载设备适航要求，形成审定要素及评审要求，可支持工业方对适航标准的理解。     

卫星遥感农业监测系统中权重优化的实例修改算法

针对播种机设计过程需求获取的复杂性和可用性低等问题，采用遥感等技术动态监测土壤、农作物生长过程中的一些参数，以优化设计需求特征，并以此为基础，提出改进的混合权重实例修改算法。该算法以相似实例检索为前提，以相似实例集中的特征相似度、问题-解特征间的关联度、问题特征间的自相关度为因子，通过矩阵乘法来构造解特征混合权重矩阵，进行实例修改。将其应用到铲式播种机的数字化设计系统中，以实现智能设计。研究结果表明新算法能有效提高机械设计结果的可用性和准确度。     

跨声速涡轮叶栅两点优化目标函数研究

针对跨声速涡轮叶栅单点优化方法难以获得整体工况性能提升、多点优化方法难以确定合理目标函数形式的问题，提出了两点优化的方法。为了节约优化时间成本，优化过程采用EIF （Equivalent inviscid flow） 模型进行数值模拟，通过添加惩罚函数保证叶栅满足设计流量和负荷要求，并采用叶栅效率线性平均的目标函数形式进行评价。选择两组跨声速涡轮叶栅进行优化设计，并利用CFD方法分析叶型变化对流场马赫数、激波和损失产生的影响。结果显示，所提出的优化设计方法在保证设计工况性能的同时，能够提升叶栅整体工况性能。通过流场分析，揭示了激波结构变化对不同工况损失影响的定性规律。综合全文研究后，给出了一种适用于跨声速涡轮叶栅两点优化设计的目标函数形式。     

Inverse design of mission success space for combat aircraft contribution evaluation

This paper presents a novel design method of the Mission Success Space (MSS) for the evaluation on aircraft contribution effectiveness. MSS concept was proposed for giving success criterion of a mission and judging the success by conventional mission effectiveness with regards to the aircraft capabilities. This space is created by the Mission Success Function (MSF) and the original Effectiveness Index Space (EIS) where empirical equations are usually assumed to be MSFs. Based on this MSS concept, this paper firstly defines the MSS-based evaluation, then further summarizes the evaluation process of the Contribution to System-of-Systems (CSS). More importantly, based on the thought of Inverse Design (ID), a new design method of MSF is presented comprehensively analyzing aircraft’s CSS in a combat mission without using any empirical MSF. The definition of MSS based ID is given and the design procedure is sequentially introduced. Two different confrontation cases are depicted with many details as the simulation validation: Air-to-ground and Penetration. There are two design variables considered for designing MSS in the latter case while only one for the former. However, in both cases, the best design is given by evaluating the Gaussian fitting performance of CSS.     

Effects of stability margin and thrust specific fuel consumption constrains on multi-disciplinary optimization for blended-wing-body design

Blended-Wing-Body(BWB) configuration, as an innovative transport concept, has become a worldwide research focus in the field of civil transports development. Relative to the conventional Tube-And-Wing(TAW) configuration, the BWB shows integrated benefits and serves as a most promising candidate for future ‘‘green aviation". The objective of the present work is to figure out the effects of the stability margin and Thrust Specific Fuel Consumption(TSFC) on the BWB design in the framework of Multi-Disciplinary Optimization(MDO). A physically-based platform was promoted to study the effect static stability margin and engine technology level. Low-order physically based models are applied to the evaluation of the weight and the aerodynamic performance. The modules and methods are illustrated in detail, and the validation of the methods shows feasibility and confidence for the conceptual design of BWB aircrafts. In order to find out the relation between planform changes and the selection of stability and engine technology level, two sets of optimizations are conducted separately. The study proves that these two factors have dominant effects towards the optimized BWB designs in both aerodynamic shapes, weight distribution, which needs to be considered during the MDO design process. A balance diagram analysis is applied to find out a reasonable static stability margin range. It can be concluded that a recommended stability margin of a practical BWB commercial aircraft can be half of that of a conventional TAW design.     

Hypersonic vehicle aerodynamic design using modified sequential approximate optimization

Hypersonic vehicles are receiving increased attention within the aerospace community due to their high cruise speed and long-range capabilities. In this paper, a modified Sequential Approximate Optimization method is proposed for an optimized aerodynamic design of a hypersonic vehicle. As part of this approach, a constrained experimental design method is developed to handle the constraints more efficiently. A radial basis function is used to surrogate time-consuming CFD analysis. An efficient and more robust numerical mesh morphing scheme for the hypersonic vehicle is developed for the generation of high-quality meshes. Within this paper, a novel adaptive infilling strategy is proposed which uses an inaccurate search technique coupled with an elite archive. This allows the location of a more promising sample region and hence improves the surrogate accuracy, thereby further enhancing the optimization efficiency. A hypersonic vehicle aerodynamic design problem is solved using the proposed approach and satisfactory results are obtained at much lower computational costs. The lift-to-drag ratio is increased by 23.8% when compared with the base configuration while also satisfying the volume and lift constraints. The pressure and Mach contours have been compared with those of the base configuration and the results demonstrate the strength of the optimized configuration. The modified sequential approximate optimization for designing an improved hypersonic vehicle is worth referencing in future work.