超高分子量聚乙烯纤维混凝土的基本力学性能

针对C70等级高强混凝土,设计了4种超高分子量聚乙烯纤维掺量混凝土,通过立方体抗压、劈裂抗拉和四点弯曲抗折试验,分析了纤维掺量对混凝土力学性能的影响。结果表明:超高分子量聚乙烯纤维对混凝土的抗压强度增强作用不明显,但较大提高了混凝土的抗拉强度和抗折强度,且对混凝土有很好的阻裂、增韧效果。在纤维体积掺量为0.3%~0.5%时,劈裂抗拉强度提高25%以上;掺量0.5%时,弯曲抗折强度提高率超过23%。     

预氧化聚碳硅烷（PCS）纤维的无机化过程

针对预氧化PCS纤维无机化过程进行了研究 ,探讨了烧成过程中预氧化PCS纤维的投放量及保护气体流量等因素对纤维烧成过程的影响。实验发现烧成过程中产生的小分子气体活性基团阻止链自由基的结合 ,从而对纤维的进一步裂解起促进作用     

潜艇结构强度研究的新近进展

本文从结构材料、结构形式、非线性分析、组合壳体和端盖强度以及结构的减振降噪等方面论述了潜艇结构强度研究的新近进展,并指出了今后的研究方向。     

求取潜艇声反射强度的新方法

分析主动声自导鱼雷攻击潜艇或水面舰艇的作战效果时,目标强度的求取是一个比较困难的问题。本文在分析有关潜艇目标强度的讨论及计算方法的基础上,提出了新的理想潜艇目标强度随舷角变化的关系曲线和一种新的求解目标强度的方法。     

基于主动相位控制的脉冲激光相干合成技术

提出并验证了基于随机并行梯度下降(SPGD)算法的主动相位控制脉冲激光相干合成方案.利用低通滤波器滤除脉冲激光光强变化导致的性能评价函数起伏,提取出相位噪声导致的性能评价函数变化,然后将这个低通滤波后的性能评价函数用于SPGD算法的极值寻优过程,从而实现脉冲激光的锁相.对该方案进行了理论分析和数值模拟,并进行了两路脉冲激光相干合成实验.实验结果表明,当系统从闭环到开环时,系统性能评价函数均值提高到开环的1.6倍,干涉条纹长曝光对比度从0提高到0.43.在该方案中,通过增加合成脉冲激光路数,并在各路脉冲激光中引入多级功率放大器,能够得到更高的合成功率输出.     

光纤激光水听器的PGC实时全数字解调系统

概述了基于麦克尔逊干涉仪的光纤激光水听器的相位载波零差法(PGC)调制解调原理,通过数学推导及仿真,分析了调制信号和混频信号的频差是导致全数字化解调结果错误的主要因素之一。针对该诱导因素提供了可行的解决方案,并实现了基于DSP的1 MHz采样频率下使用PGC方法的全数字实时解调系统。对低频水声波段800Hz水声信号进行解调,实验结果表明:解调信号波形良好。     

基于动力学仿真的6×6轮式越野车辆总体性能评价

为分析和评价某型6×6轮式越野车辆的总体设计性能,建立了整车多刚体动力学模型、刚柔耦合动力学模型以及悬架系统台架试验模型,计算了整车固有特性,依次进行了悬架系统运动学、行驶动力学、操纵稳定性分析。在计算车体和悬架摆臂结构模态的基础上,考核了典型行驶工况下车体和悬架部件结构的动态强度,依据国家相关标准,利用仿真结果对6×6整车设计进行了系统的评价,指出了该越野车总体设计性能的不足,为其进一步改进和优化设计提供了参考依据。研究方法对其他轮式越野车辆系统的设计和评价具有一定的参考价值。     

U型BFRP箍筋试件受剪试验分析

针对U型箍筋抗剪试验缺乏强度折减实践依据的问题,设计15个配有BFRP箍筋的C30混凝土U型试件。在BFRP箍筋两侧用套筒将其锚固,弯折成U型,箍筋两端采用穿心千斤顶施加荷载,逐渐加载至BFRP箍筋破坏。通过分析试验数据,建立试件受力模型,可知弯折部位锚固长度对BFRP箍筋强度折减有较大影响,最大折减为原强度的65%;随着锚固长度的增加,BFRP箍筋强度呈线性增加至某个定值;最后推导出U型BFRP箍筋强度折减公式。     

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.     

Numerical investigation on cooling performance of filter in a pyrotechnic gas generator

As a key part of the pyrotechnic gas generator,the filter not only removes the particulate matter but also cools the hot gas to a safe level.This paper aims to improve the understanding of the basic heat and flow phenomenon in the gas generator.The pyrotechnic gas generator is modelling by a simplified filter structure with fiber arrays.A finite-volume model of the heat and fluid flow is proposed to simulate the detailed multi-dimensional flow and energy conversion behaviors.Several verification results are in good agreement with data in different references.Simulation results demonstrate that the filter can not only absorb heat from the gas but also cause the high intensity enhancement of the heat transfer.The per-formance difference between inline and staggered arrays is also discussed.The findings of the study put a further prediction tool for the understanding and design of the filter system with fibers.