复合固体推进剂等效力学性能VCFEM细观预示方法

根据固体推进剂的细观结构特征,采用等圆最优装载方式生成代表性体积单元(Representative Volume Element,RVE)模型,并结合Voronoi单元有限元方法(Voronoi Cell Finite Element Method,VCFEM)和均匀化方法,发展了一种可预示固体推进剂等效力学性能的数值分析方法,从而得到体分比和组分材料对等效模量和等效泊松比的影响规律。为证明该方法的有效性,设计一个对称数值模型,通过对该方法和传统有限元方法的节点位移结果的比较,发现两者之间的相对误差小于5%,且VCFEM用少量单元就完成了分析,提高了计算效率。通过对不同细观结构下推进剂RVE模型的计算,发现随着夹杂体分比的增大,夹杂的颗粒增强效应越明显,基体材料的变化比夹杂材料对等效力学性能有着更加显著的影响。     

固体推进剂裂纹摩擦热点形成细观模型分析

分析机械撞击载荷作用下复合固体推进剂内部裂纹摩擦形成热点过程。研究在压应力与剪切应力作用下闭合裂纹滑移、扩展、摩擦生热、热扩散、推进剂热分解及与气相产物相互作用。利用断裂力学、热传导、推进剂热分解动力学方法,建立裂纹摩擦热点细观模型。通过模型数值计算,探讨推进剂裂纹摩擦产生高温热点的过程和条件。分析计算表明裂纹摩擦和扩展可导致推进剂形成高温热点。     

过氯酸铵 (AP) 爆燃的模拟

本文提出一个描述AP爆燃的物理化学模型,并计算了AP晶粒在10～800大气压下的爆燃速度、压力指数、燃面温度等参数值,计算结果和T.L. Boggs等人的实验结果相符文中提出AP爆燃过程中,在低压和高压下,可能存在着两种不同的凝聚相反应机理,并用以解释Boggs的实验现象。此外,本文还提出了一种描述绝热体系中,预混火焰燃烧时的化学反应速度表示式和计算方法,使气相温度梯度及热传导的计算简单合理,这也是本模拟研究取得成功的因素之一。     

利用化学键能评估火箭推进剂的能量特性

本文介绍利用化学键能评估火箭推进剂的能量特性的方法     

Thermal decomposition of ammonium perchlorate catalyzed with CuO nanoparticles

Ammonium perchlorate (APC) is the most common oxidizer in use for solid rocket propulsion systems. However its initial thermal decomposition is an endothermic process that requires 102.5 J·g⁻¹. This manner involves high activation energy and could render high burning rate regime. This study reports on the sustainable fabrication of CuO nanoparticles as a novel catalyzing agent for APC oxidizer. Colloidal CuO nanoparticles with consistent product quality were fabricated by using hydrothermal processing. TEM micrographs demonstrated mono-dispersed particles of 15 nm particle size. XRD diffractogram demonstrated highly crystalline material. The synthesized colloidal CuO particles were effectively coated with APC particles via co-precipitation by using fast-crash solvent–antisolvent technique. The impact of copper oxide particles on APC thermal behavior has been investigated using DSC and TGA techniques. APC demonstrated an initial endothermic decomposition stage at 242 °C with subsequent two exothermic decomposition stages at 297.8 °C and 452.8 °C respectively. At 1 wt%, copper oxide offered decrease in initial endothermic decomposition stage by 30%. The main outcome of this study is that the two main exothermic decomposition peaks were merged into one single peak with an increase in total heat release by 53%. These novel features can inherit copper oxide particles unique catalyzing ability for advanced highly energetic systems.     

Recent advances in catalytic combustion of AP-based composite solid propellants

Composite solid propellants (CSPs) have widely been used as main energy source for propelling the rockets in both space and military applications. Internal ballistic parameters of rockets like characteristic exhaust velocity, specific impulse, thrust, burning rate etc., are measured to assess and control the performance of rocket motors. The burn rate of solid propellants has been considered as most vital parameter for design of solid rocket motors to meet specific mission requirements. The burning rate of solid propellants can be tailored by using different constituents, extent of oxidizer loading and its particle size and more commonly by incorporating suitable combustion catalysts. Various metal oxides (MOs), complexes, metal powders and metal alloys have shown positive catalytic behaviour during the com-bustion of CSPs. These are usually solid-state catalysts that play multiple roles in combustion of CSPs such as reduction in activation energy, enhancement of rate of reaction, modification of sequences in reaction-phase, influence on condensed-phase combustion and participation in combustion process in gas-phase reactions. The application of nanoscale catalysts in CSPs has increased considerably in recent past due to their superior catalytic properties as compared to their bulk-sized counterparts. A large surface-to-volume ratio and quantum size effect of nanocatalysts are considered to be plausible reasons for improving the combustion characteristics of propellants. Several efforts have been made to produce nanoscale combustion catalysts for advanced propellant formulations to improve their energetics. The work done so far is largely scattered. In this review, an effort has been made to introduce various combustion catalysts having at least a metallic entity. Recent developments of nanoscale combustion catalysts with their specific merits are discussed. The combustion chemistry of a typical CSP is briefly discussed for providing a better understanding on role of combustion catalysts in burning rate enhancement. Available information on different types of combustion nanocatalysts is also presented with critical comments.     

8031单片机在氩气自动焊接过程中的应用

在焊接流水线过程中,应用单片机进行控制,目前国内尚不多见。本文介绍了使用单片机控制氩气焊枪的方法,实现了焊接过程自动化,提高了产品质量和工作效率。本文对于单片机在工业上的实际应用具有一定的参考价值。     

偶联剂在固体推进剂填料改性中的应用研究

本文采用硅烷类和钛酸酯类偶联剂对固体推进剂中的硝酸铵填料进行表面改性。改性后的硝酸铵接触角增大,表面张力降低且具有明显的疏水性。并证实偶联剂可以增强填料与粘结体系之间的界面相互作用。     

CALCULATION OF BURNING RATE CHARACTERISTICS IN ACCELERATED FIELD FOR SOME ALUMINIZED SOLID PROPELLANTS

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气泡混合轻质土的吸水特性和抗冻融循环性能

利用自制的高效复配起泡剂,制作了气泡混合轻质土试样,探讨了吸水性与轻质土密度的关系,评价了气泡混合轻质土的抗冻融循环性能。试验结果表明,随着浸水时间的延长,轻质土吸水逐渐达到饱和,试样的密度趋向于一个稳定值;气泡混合轻质土由于气泡的作用,具有一定的抗冻融性能,因而在冻融循环环境中使用气泡混合轻质土是可行的。