考虑测试性设计缺陷修正延时的测试性增长模型建模与评价方法

针对现有测试性增长模型忽略了测试性设计缺陷的修正延时过程，进而导致测试性增长模型（TGM）跟踪与预计精度低的问题，提出了一种考虑测试性设计缺陷修正延时的测试性增长模型建模理论与方法。首先分析测试性设计缺陷识别与修正之间的延时机理，得到剩余测试性设计缺陷（TDL）具有先增后减的铃形变化趋势；在此基础上，分别以Gamma、Raleigh和Delay-S 3种曲线拟合剩余测试性设计缺陷（RTDL）变化趋势，研究建立基于以上3种曲线考虑修正延时的测试性增长模型；最后，以某机载稳定跟踪平台测试性增长试验数据验证测试性增长模型拟合、跟踪及预计效能。研究结果表明：基于该测试性增长试验数据，Gamma曲线可以精确地拟合剩余测试性设计缺陷变化规律，测试性增长模型跟踪和预计精度可达到10^-2数量级。     

叶片飞脱下转子动力学响应实验

为了研究大涵道比涡扇发动机叶片飞脱时动力学响应,更好地进行发动机安全性设计,根据相似理论设计了包含叶片飞脱装置的突加不平衡实验系统并进行了实验验证。研究结果表明:设计的突加不平衡实验系统,与某型验证机相似度高,代表性强,能够有效可控地进行突加不平衡实验,重复性好,机理清晰且飞脱不平衡量大,能够真实地模拟发动机叶片飞脱响应。通过实验发现,当大突加不平衡发生时,频谱出现超次谐波并且冲击系数由于挤压油膜阻尼器限幅作用并不呈现线性关系,因而在后续研究中还应注意限幅导致的碰摩问题。      

Sliding mode control design for oblique wing aircraft in wing skewing process

When the wing of Oblique Wing Aircraft (OWA) is skewed, the center of gravity, inertia and aerodynamic characteristics of the aircraft all significantly change, causing an undesirable flight dynamic response, affecting the flying qualities, and even endangering the flight safety. In this study, the dynamic response of an OWA in the wing skewing process is simulated, showing that the three-axis movements of the OWA are highly coupled and present nonlinear characteristics during the wing skewing. As the roll control efficiency of the aileron decreases due to the shortened control arm in an oblique configuration, the all-moving horizontal tail is used for additional roll and the control allocation is performed based on minimum control energy. Given the properties of pitch-roll-yaw coupling and control input and state coupling, and the difficulty of establishing an accurate aerodynamic model in the wing skewing process due to unsteady aerodynamic force, a multi-loop sliding mode controller is formulated by the time-scale separation method. The closed-loop simulation results show that the asymmetric aerodynamics can be balanced and that the velocity and altitude of the aircraft maintain stable, which means that a smooth transition is obtained during the OWA’s wing skewing.     

组合临界流文丘里喷嘴空气流量测量方法高空舱应用分析

为满足发动机高空试验低流速进气条件下空气流量精确测量,减小进气导管气流附面层影响,弱化空气流量测量与被试发动机相关性。分析了单件/组合临界流文丘里喷嘴的工作特性,给出了组合临界流文丘里喷嘴(ACFVN)空气流量计算方法,依据给定试验发动机和高空舱尺寸设计了临界流文丘里喷嘴组合结构,得到了组合临界流文丘里喷嘴在高空舱应用的控制方法和测试布局。采用小尺寸喷嘴对组合喷嘴设计和应用方法进行了验证,结果表明:采用打开/关闭喷嘴数量和调节进气压力两种组合方式在高空舱内应用方法可行,测试布局满足测量要求,下游发动机进口截面气流紊流度优于0.3%,满足发动机高空模拟试验要求。      

三维叶轮机叶片黏性反问题设计改进方法

提出了一种改进的适用于三维黏性流场的叶轮机叶片反问题设计方法。该方法假设叶片的中弧线具有虚拟移动速度,其位移量由目标载荷与实际载荷的差值计算,并利用黏性底层厚度进行限制。采用三次B样条曲线插值方法对叶片中弧线进行光顺,新叶型通过更新后的中弧线和给定的叶片厚度得到。算例验算结果表明:该方法能够根据设计意图对叶型进行修改,鲁棒性强,收敛速度快,叶片的可变自由度高,不依赖于特定的网格和求解器,具备一定的通用性。      

Assessment on critical technologies for conceptual design of blended-wing-body civil aircraft

Civil aviation faces great challenges because of its robust projected future growth and potential adverse environmental effects. The classical Tube-And-Wing(TAW) configuration following the Cayley's design principles has been optimized to the architecture's limit, which can hardly satisfy the further requirements on green aviation. By past decades' investigations the BlendedWing-Body(BWB) concept has emerged as a potential solution, which can simultaneously fulfill metrics of noise, emission and fuel burn. The purpose of the present work is to analyze the developments of critical technologies for BWB conceptual design from a historical perspective of technology progress. It was found that the high aerodynamic efficiency of BWB aircraft can be well scaled by the mean aerodynamic chord and wetted aspect ratio, and should be realized with the trade-offs among stability and control and low-speed performance. The structure concepts of non-cylinder pressurized cabin are of high risks on weight prediction and weight penalty. A static stability criterion is recommended and further clear and adequate criteria are required by the evaluations of flying and handling qualities. The difficulties of propulsion and airframe integration are analyzed. The energy to revenue work ratios of well-developed BWB configurations are compared,which are 31.5% and 40% better than that of TAW, using state-of-art engine technology and future engine technology, respectively. Finally, further study aspects are advocated.     

Design and analysis of a truss deployable antenna mechanism based on a 3UU-3URU unit

Space deployable structures with large calibers, high accuracy, and large folding ratios are indispensable equipment in the aerospace field. Given that the single-DOF 3RR-3RRR deployable unit cannot be fully folded, this study proposes a 3UU-3URU deployable unit with two kinds of DOF: folding movement and orientation adjustment. First, based on the G-K formula, the DOF of the 3UU-3URU unit is analyzed. Then, the 3UU-3URU unit is used to construct a deployable truss antenna with a curved surface, and the DOF of the whole deployable antenna containing multiple 3UU-3URU units is calculated. The structural design of a deployable antenna with two loops is carried out with specific parameters and geometric relations. Next, a DOF simulation of a basic combination unit composed of three 3UU-3URU units is performed. Finally, a prototype of the basic combination unit is manufactured, and the DOF of the mechanism is experimentally verified.     

模块化核动力航天器设计及其关键技术

为提高核动力航天器关键技术的可继承性与可扩展性,缩短核动力航天器研发周期,降低研发成本,本文通过总结国外核动力航天器发展现状,梳理核动力航天器研制特点,结合模块化航天器概念及设计原则,首次提出模块化核动力航天器概念。将核动力航天器分为核电源模块、平台中心模块、载荷模块3大独立模块,并针对体系架构设计提出3层建设方案,针对模块化核动力航天器梳理关键技术难点,为后续项目研究提供应用参考。     

Contingency target assessment,trajectory design,and analysis for NASA’s NEA scout solar sail mission

The presented study examines contingency target selection and trajectory design for NASA’s Near-Earth Asteroid Scout mission under the assumption of a missed lunar gravity assist. Two previously considered asteroids are selected as potential targets for the given scenario based on favorable orbital characteristics for launch dates ranging from June 27, 2020 through July 26, 2020. Initially, a simplified circular restricted 3-body problem + ideal solar sail model is utilized to survey trajectory options for a month-long launch window. Selected solutions from this data set are then converged in an N-body ephemeris + non-ideal sail model. Results suggest that NEA Scout can still perform asteroid rendezvous mission under the missed lunar gravity assist scenario with new targets, 2019 GF1, 2018 PK21, and 2007 UN12, based on the target launch dates. Further target assessment is carried out for 165 days beyond the current June 27, 2020 launch date.     

飞行器智能设计愿景与关键问题

未来飞行器正朝着多元化、无人化和智能化的方向发展，高超声速、超隐身和变体等新型飞行器不断涌现。而传统飞行器解耦分拆的设计方法越来越难以满足未来飞行器综合性能全面提升的要求，只有通过整体化设计才能充分发掘飞行器的潜能。通过分析传统飞行器设计中存在的问题，提出满足全生命周期要求的飞行器智能设计体系理念，利用知识库的构建将智能赋予飞行器平台系统设计、制造生产和运维这3个阶段，并通过数字孪生技术进行飞行器全生命周期的仿真、分析和预测，以对飞行器设计、运行等数据进行更新，使该体系形成闭环。就飞行器智能设计体系中需要的关键技术及涉及的科学问题等进行了讨论，并给出了未来发展方向以供参考。