红外窗口内冷防热机理及其性能预测

给出了红外窗口内冷防热机理和防热性能预测.以液氨作为冷却剂在窗口内通道流动,利用液氨由液态转化为气态的相变过程中大量吸热的特性,达到冷却窗口的目的.并采用有限元方法计算外部具有对流加热,内部有冷却剂吸热的窗口材料温度分布.本文计算结果与地面电弧加热器实验测量结果作了比较,两者较为吻合,验证了防热预测方法的可行性.     

固体火箭发动机对交变环境温度瞬态响应的研究

在阐述了环境温度方程、传热方程和粘弹性本构关系的基础上,用有限元法求解了固体火箭发动机对交变环境温度的温度和应力响应,给出了发动机中的温度分布和应力分布,得出了发动机中危险部位和危险季节的结论。     

低功率激光-TIG电弧复合焊接不锈钢熔深研究

建立了一套低功率YAG脉冲激光-TIG电弧复合热源焊接系统,并用本系统对不锈钢1Cr18Ni9Ti进行焊接.研究了3种热源作用下不锈钢的焊缝熔深.通过引入焊缝有效热输入概念,对复合热源影响熔深的机理进行了分析.     

氧化剂含量和粒度对NEPE推进剂燃速影响的模型化

以高能固体推进剂热分解特性和燃烧模型的研究成果为基础,建立了由化学结构参数计算NEPE推进剂的燃速和压强指数的公式,计算了氧化剂组分含量和粒度对燃烧性能的影响。经验证,计算结果与实测燃速值的偏差全部在±20%以内,其中80%的偏差在±10%以内。这说明所建立的模型基本合理,编制的NEPE类推进剂燃速计算程序基本可行。     

非牛顿特性对重载点接触热弹流润滑的影响

采用近似完全数值解法对HKD-1型航空润滑油进行了重载点接触热弹流分析,将两种不同流变模型下的计算结果进行比较,并进行了试验验证.结果表明:重载情况下,润滑油的非牛顿特性较显著,非牛顿特性对于弹流润滑中润滑油的温度、剪应力和拖动力影响较大,对压力分布影响较小.采用牛顿模型计算误差非常大,采用Evans-Johnson模型计算精度较高.滑滚比增加,油膜温升增加显著,压力变化不大,只是二次压力峰的峰值有所减小.      

基于多体系统动力学的旋翼桨叶响应计算方法

在中等变形梁的基础上引入增广转换矩阵,为解决桨叶动能项推导编程计算较为复杂的问题,建立了一种新的递推计算方法。该方法在原有的转换矩阵基础上进行了增广,建立了相邻运动坐标系间动能项引起的质量、阻尼、刚度和广义力递推计算方法。以法国SA349/2小羚羊直升机的试飞测试数据为依据,验证了方法的有效性。     

双马来酰亚胺改性酚醛型环氧树脂性能研究

采用双马来酰亚胺(BMI)改性酚醛型环氧树脂(F-51)/芳香胺(DAMI)固化体系。采用DSC,TGA和TMA等仪器考察BMI含量对改性体系的固化行为、力学性能及热稳定性的影响,并用扫描电镜(SEM)研究材料断面的形态结构。结果表明,随着体系中BMI比例的增加,体系固化放热峰向高温区移动,总反应热减小,BMI的加入可以提高材料的力学性能和热稳定性,改性后材料断裂面的形态呈现韧性断裂特征。     

振动能量流的测量不确定度评定

介绍了管壁振动能量流的测试方法和不确定度来源,并进行了详细的分析和评定.     

压力和DNTF含量对DNTF-CMDB推进剂热分解动力学的影响

用高压差示扫描量热(PDSC)、热重等热(TG-DTG)分析技术,研究了不同压力和DNTF含量对4种DNTF-CMDB推进剂热分解行为及动力学的影响。结果表明,DNTF含量对CMDB推进剂的热分解特征量有明显影响,分解热ΔHd与ΔT的比值(ΔHd/ΔT)随DNTF加入量的增加而下降,同时DNTF的加入也影响PDSC和DTG的峰形。高压下DNTF-CMDB推进剂的活化能均较常压小,高压使初始分解的反应速率常数提高,且随DNTF含量增加,活化能逐渐增大,分解初始阶段反应速率常数减小,6 MPa下的结果与燃速随DNTF含量增加呈下降的趋势相一致。     

Specific grinding energy and surface roughness of nanoparticle jet minimum quantity lubrication in grinding

Nanoparticles with the anti-wear and friction reducing features were applied as cooling lubricant in the grinding fluid. Dry grinding, flood grinding, minimal quantity of lubrication（MQL）, and nanoparticle jet MQL were used in the grinding experiments. The specific grinding energy of dry grinding, flood grinding and MQL were 84, 29.8, 45.5 J/mm³, respectively. The specific grinding energy significantly decreased to 32.7 J/mm³ in nanoparticle MQL. Compared with dry grinding, the surface roughness values of flood grinding, MQL, and nanoparticle jet MQL were significantly reduced with the surface topography profile values reduced by 11%, 2.5%, and 10%,respectively, and the ten point height of microcosmic unflatness values reduced by 1.5%, 0.5%,and 1.3%, respectively. These results verified the satisfactory lubrication effects of nanoparticle MQL. MoS₂, carbon nanotube（CNT）, and ZrO₂ nanoparticles were also added in the grinding fluid of nanoparticle jet MQL to analyze their grinding surface lubrication effects. The specific grinding energy of MoS₂ nanoparticle was only 32.7 J/mm³, which was 8.22% and 10.39% lower than those of the other two nanoparticles. Moreover, the surface roughness of workpiece was also smaller with MoS₂ nanoparticle, which indicated its remarkable lubrication effects. Furthermore,the role of MoS₂ particles in the grinding surface lubrication at different nanoparticle volume concentrations was analyzed. MoS₂ volume concentrations of 1%, 2%, and 3% were used.Experimental results revealed that the specific grinding energy and the workpiece surface roughness initially increased and then decreased as MoS₂ nanoparticle volume concentration increased.Satisfactory grinding surface lubrication effects were obtained with 2% MoS₂ nanoparticle volume concentration.