H2O2/HTPB固液混合发动机点火试验研究

利用H2O2催化分解原理,设计了烃类燃料在催化分解的90%H2O2中能燃烧的点火器,然后采用该点火器进行H2O2/HTPB固液混合发动机点火试验研究.试验结果表明,该点火器能够成功启动H2O2/HTPB固液混合发动机,且当混合比偏离最佳混合比后,发动机的燃烧效率降低.     

液体推进剂消耗对大型卫星结构动特性的影响分析

为了研究液体推进剂消耗对某大型卫星结构动特性的影响,采用简化的“弹簧-质量”模型分析了推进剂消耗对结构动特性的影响趋势;基于MSC.PATRAN/NASTRAN给出了动力学分析过程中液体推进剂的等效建模和分析方法,包括梁单元法、附加质量法、“RBE3 -质量点”单元法和虚拟质量法等;建立了该卫星结构的有限元模型,进行了结构动力学特性和动响应分析,讨论了液体推进剂消耗对其动特性的影响规律.研究结果表明:随着推进剂的消耗,卫星整体振型的固有频率逐渐增大,而部分局部振型的固有频率保持不变;随着推进剂的消耗,卫星仪器安装板动力学响应峰值逐渐增大,所对应的频率也逐渐增大.     

低温推进剂供应管道系统充填过程的动力学模型

研究了低温推进剂液体火箭发动机供应管道系统充填过程的建模问题。低温推进剂的充填相变过程采用均相模型,对推进剂充填管道系统进行有限元分割,应用基本守恒定律于充满推进剂的单元和充满气体的单元,两相单元采用等效流容方程,建立了低温推进剂管道充填过程的有限元状态变量模型。充填的容腔视为两相单元,建立了其动力学模型。利用本文的模型,对液氢、液氧推进剂的管道充填过程进行了仿真计算,给出了有关计算结果。     

某型枪弹火药性能对内弹道性能影响试验研究

通过对某型枪弹 (如经过技术处理的正常弹、减量弹、加温弹、干燥弹及受潮弹 )初速和最大膛压的测定 ,得出火药的药量、初温及挥发份对内弹道性能 (如膛压、初速 )有较大影响 ,因此 ,必须严格控制弹药的储存条件及装药量。     

复合推进剂中硝酸铵的改性研究

在分析硝酸铵的多晶现象和吸湿特性的基础上 ,探讨了硝酸铵的改性技术。采用热分析法研究了无机添加剂对硝酸铵晶型转变的影响 ,并用高分子表面处理剂对硝酸铵进行表面处理。结果表明 ,这种方法可以有效地改善硝酸铵的晶体结构和吸湿特性 ,为硝酸铵在复合推进剂中的应用提供了实验和理论依据。     

基于能量耗散的药柱粘弹性累积损伤

基于不可逆能量耗散的损伤变量定义方法和动态线粘弹性理论,建立了固体推进剂累积损伤模型,利用不同拉伸速率下的试验数据,拟合得到了推进剂破坏耗散能表达式,进而给出了推进剂在周期应力响应下的累积损伤计算式,并讨论了周期应力幅值和频率对累积损伤的影响,最后对某舰载发动机药柱进行了累积损伤及使用寿命分析。提出的累积损伤分析方法,为固体发动机贮存寿命预估提供了一条有益的技术途径。     

水解法测定发射药钝感剂浓度分布实验条件优化

对水解法测定发射药中钝感剂浓度分布实验条件进行了优化。结果表明,包覆材料选用氯丁橡胶胶粘剂效果最好;水解在沸碱液中进行时,残药表面光滑且能提高测试效率;残药干燥条件为:在100℃干燥20 m in。     

Analysis on damage characteristics and detonation performance of solid rocket engine charge subjected to jet

To further explore the damage characteristics and impact response of the shaped charge to the solid rocket engine (SRE) in storage or transportation, protective armor was designed and the shelled charges model (SCM)/SRE with protective armor impacting by shaped charge tests were conducted. Air overpressures at 5 locations and axial acceleration caused by the explosion were measured, and the experimental results were compared with two air overpressure curves of propellant detonation obtained by related scholars. Afterwards, the finite element software AUTODYN was used to simulate the SCM impacted process and SRE detonation results. The penetration process and the formation cause of damage were analyzed. The detonation performance of TNT, reference propellant, and the propellant used in this experiment was compared. The axial acceleration caused by the explosion was also analyzed. By comprehensive comparison, the energy released by the detonation of this propellant is larger, and the HMX or Al particles contained in this propellant are more than the reference propellant, with a TNT equivalent of 1.168–1.196. Finally, advanced protection armor suggestions were proposed based on the theory of woven fabric rubber composite armor (WFRCA).     

Deconsolidation and combustion performance of thermally consolidated propellants deterred by multi-layers coating

Both heating and solvent-spray methods are used to consolidate the standard grains of double-base oblate sphere propellants plasticized with triethyleneglycol dinitrate (TEGDN) (TEGDN propellants) to high density propellants. The obtained consolidated propellants are deterred and coated with the slow burning multi-layer coating. The maximum compaction density of deterred and coated consolidated propellants can reach up to 1.39 g/cm³. Their mechanic, deconsolidation and combustion performances are tested by the materials test machine, interrupted burning set-up and closed vessel, respectively. The static compression strength of consolidated propellants deterred by multi-layer coating increases significantly to 18 MPa, indicating that they can be applied in most circumstances of charge service. And the samples are easy to deconsolidate in the interrupted burning test. Furthermore, the closed bomb burning curves of the samples indicate a two-stage combustion phenomenon under the condition of certain thickness of coated multi-layers. After the outer deterred multi-layer coating of consolidated samples is finished burning, the inner consolidated propellants continue to burn and breakup into aggregates and grains. The high burning progressivity can be carefully obtained by the smart control of deconsolidation process and duration of consolidated propellants. The preliminary results of consolidated propellants show that a rapid deconsolidation process at higher deconsolidation pressure is presented in the dynamic vivacity curves of closed bomb test. Higher density and higher macro progressivity of consolidated propellants can be obtained by the techniques in this paper.     

NEPE类推进剂燃烧模拟

在分析、研究硝胺和AP CMDB推进剂燃烧模型的基础上,结合NEPE类推进剂的配方和燃烧性能特点,建立了NEPE类推进剂燃烧的物理模型,并进行了燃速和压强指数的理论计算。结果表明,几乎100%的计算结果都在实验值的±10%范围内。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。