基于增广Burgers方程的音爆远场计算及应用

音爆的精确模拟对于超声速客机的低音爆研究与设计意义重大。由于计算能力的限制,客机巡航高度的音爆全场直接模拟目前还难以实现。现有的音爆预测方法一般分为两步,先通过超声速线化理论或计算流体力学的方法得到音爆近场的过压值（Over-pressure）分布,再通过声学理论将近场声压信号推进至远场,以获得飞行器的地面音爆信号。在远场计算中,传统的波形参数法没有考虑音爆传播过程中的经典吸收和分子驰豫效应所造成的声能损失,得到的激波没有厚度,导致计算得到的远场声压级不准确。基于算子分裂法,开展了非线性声学中的增广Burgers方程的数值解法研究。通过计算第二届音爆预测研讨会（SBPW-2）发布的两个标准算例,验证了该方法可以实现地面音爆波形的精确预测。发现在近场声压信号前加入一段无幅值的缓冲信号可以有效提升"N"波上升时间的模拟精度。网格收敛性研究表明适当加密计算网格是有必要的。在此基础上研究了大气声吸收对地面波形的影响,发现分子驰豫效应的影响要强于经典吸收。最后,研究了不同湿度、温度对地面音爆波形的影响,发现干燥、低温的环境对音爆信号的过压值有抑制作用。     

加油机喷流对受油机的气动干扰机理

针对软式平台(HDB)、软式吊舱(HDP)和硬式平台(FB)3种典型加油方案研究了喷流对加油流场的影响。采用结构化多块网格和雷诺平均Navier-Stokes(RANS)方程,通过带涡轮动力模拟器(TPS)和翼身组合体构型DLR-F6对数值方法进行了验证。通过对3种典型的空中加油方案进行数值模拟,并和不考虑喷流效应的空中加油流场进行对比,详细研究了不同加油方案中加油机喷流对受油机气动特性的干扰作用。结果表明:受油机升力系数、阻力系数以及低头力矩与无喷流相比均有增大。受油机在硬式平台加油方案中受喷流影响最小,但其横航向气动特性在软式吊舱加油方案中受加油机喷流影响较大。喷流对受油机的气动干扰主要表现在提高受油机来流动压、改变局部迎角以及对周边气流的引射作用,这些因素会导致受油机表面压力与无喷流相比发生较大变化。其中,局部迎角的改变是由喷流的加速效应及其对尾涡的耗散作用导致的。     

在轨流体管理技术进展和关键技术分析

综述了国外在轨流体管理技术的发展现状与趋势,分析了低温流体长期在轨贮存、在轨加注、空间流体生产等主要技术,并提出了在轨流体管理中需突破的关键技术难题。     

N-fold Bernoulli probability based adaptive fast-tracking algorithm and its application to autonomous aerial refuelling

Recently, deep learning has been widely utilized for object tracking tasks. However, deep learning encounters limits in tasks such as Autonomous Aerial Refueling (AAR), where the target object can vary substantially in size, requiring high-precision real-time performance in embedded systems. This paper presents a novel embedded adaptiveness single-object tracking framework based on an improved YOLOv4 detection approach and an n-fold Bernoulli probability theorem. First, an Asymmetric Convolutional Network (ACNet) and dense blocks are combined with the YOLOv4 architecture to detect small objects with high precision when similar objects are in the background. The prior object information, such as its location in the previous frame and its speed, is utilized to adaptively track objects of various sizes. Moreover, based on the n-fold Bernoulli probability theorem, we develop a filter that uses statistical laws to reduce the false positive rate of object tracking. To evaluate the efficiency of our algorithm, a new AAR dataset is collected, and extensive AAR detection and tracking experiments are performed. The results demonstrate that our improved detection algorithm is better than the original YOLOv4 algorithm on small and similar object detection tasks; the object tracking algorithm is better than state-of-the-art object tracking algorithms on refueling drogue tracking tasks.     

Effect of longitudinal lift distribution on sonic boom of a canard-wing-stabilator-body configuration

After the last flight of the Concorde in 2003, sonic boom has been one of the obstacles to the return of a supersonic transport aircraft to service. To reduce the sonic boom intensity to an acceptable level, it is of great significance to study the effect of lift distribution on far-field sonic boom, since lift is one of the most important contributors to an intense sonic boom. Existing studies on the longitudinal lift distribution used low-fidelity methods, such as Whitham theory, and in turn,o...     

离轨帆弹性桅杆力学性能分析

采用有限元分析软件ABAQUS分析弹性桅杆几何参数对其力学性能的影响,为离轨帆弹性桅杆设计提供一定的理论依据。结果表明:增加壳体厚度、保持弧长不变,减小曲率半径以及增大壳体截面圆心角都能有效提高离轨帆自动展开能力及弹性桅杆支撑刚度;弹性桅杆的弯曲内部应力只与材料属性、曲率半径、缠绕半径以及壳体厚度有关;曲率半径减小、壳体厚度增加都会增大弹性桅杆的弯曲内部应力,有可能会导致弹性桅杆在缠绕时发生塑性变形。因此,在对弹性桅杆设计时,需综合考虑弹性桅杆几何参数对其展开能力以及缠绕性能的影响。     

无强波构型理论发展现状研究

本文引入了一种由Busemann超声速双翼理论发展而来的无强激波构型,该构型可明显消弱超声速飞行时带来的波阻和声爆。文中分析了无强波构型的机理和气动特性,介绍了该构型理论研究和应用研究进展,并探讨了该构型在超声速飞行器设计应用中的关键性问题。该理论为未来低声爆超声速飞机的设计提供了一个全新的思路,是未来超声速/高超声速飞行器发展必要的技术基础。     

卫星在轨推进剂补加量测量方法精度研究

卫星在轨推进剂补加量的精确测量技术是在轨补加任务的关键技术之一。本文结合型号攻关结果，提出2种在轨推进剂补加量测量方法数学模型，分别是压力-体积-温度(PVT)法和超声波流量计法。首先，PVT法是一种通过补加前后受体卫星贮箱剩余量反算补加量的间接测量方法，而超声波流量计法是利用超声波顺逆流相位差进行测量的直接测量方法;其次，在推进剂补加量测量模型的基础上，进一步通过取变分的手段提出2种模型的精度分析解析模型，解析的精度分析模型不仅可用于定性分析影响测量精度的因素，还可量化评价各个因素对测量精度的影响;最后，利用现有在研单机的精度水平及精度分析解析模型分析了2种方法的测量精度，验证了方法的有效性。     

Far-field sonic boom prediction considering atmospheric turbulence effects: An improved approach

Accurate prediction of sonic boom is one of key challenges for the design of a low-boom supersonic aircraft. For most of available far-field prediction methods, the effect of atmospheric turbulence appearing in the planetary boundary layer cannot be considered, which results in remarkable inaccuracy of predicting ground-level sonic boom waveform. Although some efforts have been made to overcome the shortcoming, the turbulence effects are not yet well described so far. This article proposes an improved method by extending the two-dimensional Heterogeneous One-Way Approximation for the Resolution of Diffraction (HOWARD) equation to account for the axial and transverse convections of wind fluctuation as well as the effect of temperature fluctuation. The proposed method is validated by comparing the predictions with the flight-test data of JAXA D-SEND#1 LBM, which shows that the result of the proposed method is in better agreement with the flight-test data than that of the method without considering atmospheric turbulence effects. Then, distortion mechanism of sonic boom waveforms caused by atmospheric turbulence is analyzed by using the proposed method. It is indicated that the effect of turbulent convection makes uniform sonic-boom wavefronts irregular, which creates the condition of diffraction effect to perturb waveforms. Finally, the proposed method is applied to investigate the behavior of two types of waveforms given by the sonic boom minimization theory. Results show that a far-field waveform with a weaker initial shock is more beneficial for low-boom design of a supersonic aircraft.