一种智能型鱼雷蓄电池快速充电方案

介绍了一种智能型鱼雷蓄电池快速充电装置的新型充电理论及其硬、软件设计原理和方法．该系统使充、放电容量得到实时控制,减少了鱼雷电池充电时的极化,提高了充电速度．     

用故障树分析法排除柴油机监控系统故障

对某型舰艇柴油机监控系统运行中发现的三个故障现象,应用故障树分析法,构筑相应故障树,在此基础上进行逐项测试检查,最终完成了故障定位,修理后成功地排除了所有故障.     

L(0,1)模态导波在小管径管道弯头处的散射特性

采用实验和有限元模拟的方法研究了L(0,1)模态导波在小管径管道弯头处的模态转换和反射、透射特性,分别使用不同频率的激励信号对含不同弯曲半径弯头的管道进行检测。研究结果表明:L(0,1)模态导波在管道弯头处发生模态转换,转换成F(1,1)模态,并且其偏振方向与弯头拱背—拱腹方向一致;随着检测频率和弯曲半径的增大,反射F(1,1)模态呈减小趋势,透射F(1,1)模态呈非单调变化趋势;反射L(0,1)模态导波呈减小趋势,透射L(0,1)模态导波呈增大趋势;当检测频率或弯曲半径增大到一定程度时,两参数的变化对反射F(1,1)模态、反射L(0,1)模态和透射L(0,1)模态的影响不大。实验结果与模拟结果吻合度高,验证了模拟结果的正确性。研究结论为检测小管径含弯头管道提供了理论指导。     

超低空重装空投纵向自抗扰控制

针对超低空重装空投过程中,货物的持续移动及瞬间出舱对载机产生的干扰力矩严重影响空投任务的完成性甚至危及飞行安全的问题,提出了一种基于自抗扰理论的超低空空投运输机纵向控制律设计方法。将气动参数摄动、未建模动态等不确定因素都归结为"未知扰动",利用扩张状态观测器对扰动进行实时估计和补偿,实现了飞机内环速度和俯仰角的解耦控制,保证了系统鲁棒性,结合外环PID高度保持控制器完成整个飞行控制系统的设计。数值仿真结果表明,该系统具有良好的响应特性,且对系统不确定性具有较强的鲁棒性。     

基于定时Petri网的舰艇保障能力仿真与评估

舰艇保障是一种主要依赖后勤技术装备的专业化后勤,也是涉及并行、冲突,并受资源、装配时间等限制的复杂离散事件过程。借助定时Petri网强大的描述能力标记过程中的各种动态行为,在此基础上对包括后勤装备在内的后勤实体、保障任务、保障活动等进行建模,采用编码、转换等手段实现舰艇保障过程仿真,并使用仿真结果对后勤保障能力进行"定量计算"为主的分析评估。     

边缘化粒子概率假设密度滤波的多目标跟踪

针对复杂情况下的多目标跟踪问题,提出一种边缘化粒子概率假设密度滤波(MPF-PHD)方法。该方法首先将复杂情况下多个目标的状态向量分别提取出其中的非线性状态与线性状态。然后利用粒子概率假设密度滤波(PF-PHD)估计非线性状态,利用卡尔曼滤波(KF)估计线性状态,并把其中与非线性状态相关的线性状态估计用来优化非线性状态估计。通过对MPF-PHD方法与传统的PF-PHD方法仿真对比,验证了MPF-PHD方法有效解决了复杂情况下多目标跟踪的漏检问题,提高了多目标状态估计精度。     

低错误平层数列分割移位LDPC码构造算法研究

为降低LDPC码错误平层,提出一种基于环分类搜索的数列分割移位LDPC码构造算法。该算法具有码长、码率和列重的任意可设性,同时该类码的Tanner图围长至少为8。循环移位因子可以通过简单的代数表达式描述,从而降低内存需求。仿真结果表明,当误码率达到10-5时,数列分割移位LDPC(496,248)码相对于PEG-LDPC码获得了约1.9dB的性能提升;且随着信噪比的升高,两条译码性能曲线之间的差距将更为增大。此外,列重为3的数列分割移位LDPC码(6144,5376)在信噪比4.6dB以后并未出现明显的错误平层。该构造算法与PS-LDPC码相比在误码率达到10-8时大约获得0.25dB增益,特别在错误平层区域其译码性能优于围长为4和6的PEG构造算法,其构造复杂度和耗时也相较于PS-LDPC码和PEG-LDPC码构造算法展现出一定优势。通过基于Tanner图的诱捕集分析方法,统计(496,248)APPS-LDPC码中由8环组成的部分小型诱捕集并不存在,从而证明了其错误平层降低的原因。     

【专题】人工智能装备质量监督效能研究

近年来,人工智能技术迅速发展和渐趋成熟,在装备领域的应用大放异彩,极大地拓展了传统装备性能,特别是自主性和智能化水平。但人工智能算法本身固有的逻辑推理性差、具有不可解释性和需要学习训练等特性给人工智能装备的质量监督带来了新挑战,现有评价手段的欠缺也使人工智能装备发展在实用可靠方面充满不确定性。本文在总结归纳人工智能装备新特性拓展和质量监督新挑战的基础上,重点围绕有效提升人工智能装备的质量监督展开研究。提出应在夯实基础能力设施建设、注重日常数据采集整理、灵活技术状态管控、研究有效评价手段、强化人才队伍建设和闭环质量信息反馈与利用等六方面加强人工智能装备质量监督的措施建议,以期为人工智能装备的发展建设提供参考。     

Investigation on the process parameters of TIG-welded aluminum alloy through mechanical and microstructural characterization

Multi-pass TIG welding was conducted on plates (15×300×180 mm3) of aluminum alloy Al-5083 that usually serves as the component material in structural applications such as cryogenics and chemical processing industries. Porosity formation and solidification cracking are the most common defects when TIG welding Al-5083 alloy, which is sensitive to the welding heat input. In the experiment, the heat input was varied from 0.89 kJ/mm to 5 kJ/mm designed by the combination of welding torch travel speed and welding current. Tensile, micro-Vicker hardness and Charpy impact tests were executed to witness the impetus response of heat input on the mechanical properties of the joints. Radiographic inspection was performed to assess the joint's quality and welding defects. The results show that all the specimens displayed inferior mechanical properties as compared to the base alloy. It was established that porosity was progressively abridged by the increase of heat input. The results also clinched that the use of me-dium heat input (1-2 kJ/mm) offered the best mechanical properties by eradicating welding defects, in which only about 18.26% of strength was lost. The yield strength of all the welded specimens remained unaffected indicated no influence of heat input. Partially melted zone (PMZ) width also affected by heat input, which became widened with the increase of heat input. The grain size of PMZ was found to be coarser than the respective grain size in the fusion zone. Charpy impact testing revealed that the absorbed energy by low heat input specimen (welded at high speed) was greater than that of high heat input (welded at low speed) because of low porosity and the formation of equiaxed grains which induce better impact toughness. Cryogenic (-196 C) impact testing was also performed and the results corroborate that impact properties under the cryogenic environment revealed no appreciable change after welding at designated heat input. Finally, Macro and micro fractured surfaces of tensile and impact specimens were analyzed using Stereo and Scanning Electron Microscopy (SEM), which have supported the experimental findings.     

Preparation and characterization of HMX/EVA/hBNNSs micro-composites with improved thermal stability and reduced sensitivity

Hexagonal boron nitride nanosheets(HBNNSs)have huge potential in the field of coating materials owing to their remarkable chemical stability,mechanical strength and thermal conductivity.Thin-layer hBNNSs were obtained by a liquid-phase exfoliation of h-BN powders and incorporated into EVA coatings for improving the safety performance of 1,3,5,7-tetranitro-1,3,5,7-tetrazocane(HMX).HBNNSs and ethylene-vinyl acetate copolymer(EVA)were introduced to HMX by a solvent-slurry process.For com-parison,the HMX/EVA and HMX/EVA/graphene(HMX/EVA/G)composites were also prepared by a similar process.The morphology,crystal form,surface element distribution,thermal decomposition property and impact sensitivity of HMX/EVA/hBNNSs composites were contrastively investigated.Results showed that as prepared HMX/EVA/hBNNSs composites were well coated with hBNNSs and EVA,and exhibited better thermal stability and lower impact sensitivity than that of HMX/EVA and HMX/EVA/G composites,suggesting superior performance of desensitization of hBNNSs in explosives.