Effects of Shot Peening Process on Thermal Cycling Lifetime of TBCs Prepared by EB-PVD

Conventional two-layered thermal barrier coatings (TBCs) are prepared by electron beam physical vapor deposition (EB-PVD) with ZrO2-8 wt% Y2O3 (8YSZ) as top coat and CoCrAlY as bond coat on disk-shaped Ni based super-alloy. In this paper, three kinds of shot peening process with different lengths of operating time were adopted for bond coating. As a result, changes took place in its sur- face roughness and the surface micro-hardness. A thermal cycling test at 1 273 K×55 min and another at room temperature for 5 min were performed to study the effects of shot peening process on the thermal cycling lifetime of TBCs. It is found that a moderate shot peening process will be able to prolong the life time. The oxidation dynamic of the as-processed TBCs basically accords with the para- bolic rule, and the oxidation test also attests to the spallation between YSZ and thermal growth oxide (TGO) responsible mainly for the failure of TBCs.     

工艺参数对轻质热防护组件胶接装配性能的影响

可重复使用运载器采用轻质热防护材料和应变隔离垫作为飞行器的热防护系统,轻质热防护组件通过硅橡胶胶黏剂粘接至碳纤维复合材料蒙皮表面。为提高可重复使用飞行器轻质热防护系统粘接质量,通过实验方法研究了加压压力、加压时间、表面处理方式等对轻质热防护组件与碳纤维复合材料的粘接强度的影响。结果表明：轻质热防护组件与碳纤维复合材料的粘接强度随加压压力的增大而增大,随加压时间的增长先迅速增大,当加压时间超过7 h时缓慢增大;打磨或涂处理剂表面处理方式均能提高粘接强度,同时施加两种处理方式时提高粘接强度大于52%。     

等离子体接触器对空间站充放电的影响

针对采用100V高压电池阵的空间站结构体带电现象,提出采用等离子体接触器进行主动电位控制方案,根据此方案建立包含接触器的空间站充放电等效电路模型,研究等离子体接触器对空间站充放电过程的影响及空间站结构因素对接触器钳位效果的影响,从而了解等离子体接触器与空间站悬浮电位的耦合特性。结果表明,无论空间站处于“快速充电”还是“正常充电”情况,等离子体接触器均能有效将空间站悬浮电位钳制在合理范围内。空间站结构因素中,电池阵暴露导体面积对接触器钳位过程影响较大,结构体暴露导体面积和结构体等效电容的影响可忽略。     

面向MBD模型的工艺信息组织与重构系统

针对生产准备过程中人工逐项查看、查找MBD模型中产品制造信息工作量大、耗时长的问题,基于MBD模型中工艺信息的存储规范,对非几何信息的检索、提取、分析、重构技术进行了研究,在此基础上开发了面向MBD模型的工艺信息组织与重构系统,满足了制造过程中不同阶段、不同角色、不同专业对产品数模信息不同层次的使用需求。     

A Poisson multi-Bernoulli mixture filter with spawning based on Kullback–Leibler divergence minimization

In the classical form, the Poisson Multi-Bernoulli Mixture (PMBM) filter uses a PMBM density to describe target birth, surviving, and death, which does not model the appearance of spawned targets. Although such a model can handle target birth, surviving, and death well, its performance may degrade when target spawning arises. The reason for this is that the original PMBM filter treats the spawned targets as birth targets, ignoring the surviving targets’ information. In this paper, we propose a Kullback–Leibler Divergence (KLD) minimization based derivation for the PMBM prediction step, including target spawning, in which the spawned targets are modeled using a Poisson Point Process (PPP). Furthermore, to improve the computational efficiency, three approximations are used to implement the proposed algorithm, such as the Variational Multi-Bernoulli (VMB) filter, the Measurement-Oriented marginal MeMBer/Poisson (MOMB/P) filter, and the Track-Oriented marginal MeMBer/Poisson (TOMB/P) filter. Finally, simulation results demonstrate the validity of the proposed filter by using the spawning model in these three approximations.     

支持工艺设计的制造知识类型及层次模型

针对工艺设计人员对大量制造知识的需求问题,分析了制造知识与工艺设计的关系,按照对工艺设计的支持作用,将制造知识分为制造资源类、制造对象类和制造过程类三大类别,建立了包括零件层、属性层和数据库层的制造知识结构层次模型,以制造设备为例,采用IDEF1X方法建立了支持工艺设计的制造知识表达模型.     

基于面向对象技术的典型工艺知识库系统

建立了多层次的典型工艺结构,充分利用相似特征具有相似工艺的理论;研究了工艺查询、工艺评价和工艺设计等应用子系统的功能结构,开发了面向对象的典型工艺知识库系统。     

Development of theoretical approaches to the control of a water-treatment system

The Advanced Life Support/NASA Specialized Center of Research and Training (ALS/NSCORT) focuses on research and development of technologies to support human habitation during space missions. This research was done as part of an effort to maintain crewmembers’ water supply in a closed life-support system. The water subsystem was the primary focus of this study because water is one of the most expensive and important resources for human survival.     

A review of chatter vibration research in milling

Chatter is a self-excited vibration of parts in machining systems. It is widely present across a range of cutting processes, and has an impact upon both efficiency and quality in production processing. A great deal of research has been dedicated to the development of technologies that are able to predict and detect chatter. The purpose of these technologies is to facilitate the avoidance of chatter during cutting processes, which leads to better surface precision, higher productivity, and longer tool life. This paper summarizes the current state of the art in research regarding the problems of how to arrive at stable chatter prediction, chatter identification, and chatter control/suppression, with a focus on milling processes. Particular focus is placed on the theoretical relationship between cutting chatter and process damping, tool runout, and gyroscopic effect, as well as the importance of this for chatter prediction. The paper concludes with some reflections regarding possible directions for future research in this field.