聚氨酯阻尼材料的结构设计及其动态力学性能的研究

据聚合物阻尼性能定量化理论,设计合成了软段结构、分子量不同以及含支链的聚氨酯.动态力学性能测试表明,含聚环氧丙烷二醇(PPG,Mn=2 000)、聚己二酸二乙二醇(PDEA,Mn=2 000)、聚己二酸乙二醇(PEAG,Mn=2 000)软段的试样的温域宽和内耗峰高.当软段分子量增加时,材料的损耗因子增加.组份相同时,含支链比不含支链的聚氨酯试样的内耗峰高,阻尼值大.     

聚钛碳硅烷的结构与性能研究

通过聚碳硅烷与四丁氧基钛的反应。可以制得含钛碳化硅纤维的先驱体聚钛碳硅烷。反应物配比(Ti(OBu)_4)/PC 将直接影响产物的结构与性能。随这一比例的增加,聚钛碳硅烷的可纺性与熔点将有规律地变化。这可归因于以—Ti—O—为桥的交联结构和以—Ti(OBu)_3为侧基的悬挂结构的形成。本文研究了聚钛碳硅烷的结构与性能的关系,并以具有良好成丝性的PTC-0.02与PTC-0.04为先驱体,制得了含钛碳化硅纤维。     

军事工程用土聚水泥材料研究

土聚水泥是一种新型高性能碱激活水泥。相对硅酸盐水泥而言，土聚水泥生产能耗低、几乎无污染，是环保型建筑胶凝材料。土聚水泥在生产工艺、性能及用途等方面集有机高聚物、陶瓷、水泥等材料的特征，同时又具有独特的性能。分析了土聚水泥的生产工艺、主要矿物组成、聚合机理、主要水化产物和性能特点以及与硅酸盐水泥的区别，并对土聚水泥在战时快速抢修抢建、工程防护和洞库的修建修补等军事工程保障中的应用作了初步探讨。     

聚钛碳硅烷的新合成法及其研究

从聚硅烷(PS)与钛酸丁酯。(Ti(OBu)_4)出发,不采用任何反应促进剂直接合成了含钛碳化硅纤维的先驱体聚钛碳硅烷(PTC)。在这一反应中,PS 首先裂解成含Si—C 骨架与Si—H 键的低分子聚硅烷(LPS)。然后,由LPS 中的Si—H 键与Ti(OBu)_4的反应以及LPS 的Si—Si 骨架裂解转化为Si—C 骨架的反应制得了PTC.本文对这种新合成法所涉及的反应过程进行了研究,并比较了新旧两法得到的PTC—1与PTC—Ⅱ的结构异同,报告了以新法制得的PTC—Ⅱ为先驱体得到的含钛碳化硅纤维的优良性能。     

连续波DF/HF化学激光器喷管中氟原子复合计算

氟原子是连续波DF/HF化学激光器泵浦反应的重要参与者,其浓度分布尤其直接影响冷反应型激光器的泵浦效率及激射强度.在参与反应之前,氟原子将受到三体复合和壁面复合因素的影响而部分复合为氟分子.研究该因素对氟原子浓度的影响对激光器的分析优化是十分重要的.已有一定的实验方法可对其浓度进行测量研究,并建立了理论模型描述.将其与计算流体力学方法相结合对氟原子分布进行计算,研究了该方法的有效性,并对不同收缩段型面下氟原子复合进行了计算研究.     

泰氟隆烧蚀产物对电子密度的影响

采用WNND格式,对有泰氟隆烧蚀产物引射的化学非平衡NS方程进行了数值模拟。采用7组元纯空气化学反应和19组元、28种反应的空气—泰氟隆化学反应系统,对照计算了壁面有泰氟隆烧蚀产物引射和纯空气绕流两种流场,研究了泰氟隆烧蚀产物对电子密度的影响。     

Cu粉粒径及含量对Ni/MH电池负极放电性能的影响

为了提高Ni/MH电池中储氢电极的放电性能,以电解Cu粉为充填材料与活性物质混合制备电极,研究Cu粉粒径及含量对电极性能的影响。研究发现,Cu粉粒径越小,含量越高,电极的放电容量、高倍率放电性能、及在低温和高温下的放电能力均提高,且Cu充填电极的性能优于Ni充填电极。Cu充填电极中析氢反应的交换电流密度较大,过电势较小,说明其电催化活性好,电极反应阻力小。SEM分析发现,充放电循环后的Cu充填电极,其储氢合金颗粒表面覆盖着一层细小Cu颗粒和丝状物,这是电极性能提高的主要原因。     

聚氨酯的合成及水声性能

用甲苯-2,4-二异氰酸酯(2,4-TDI)、聚丙二醇(PPG)等原料合成了聚氨酯预聚体,以3,3-二氯-4,4-二氨基二苯甲烷(MOCA)、三羟甲基丙烷(TMP)为扩链剂合成了聚氨酯,在脉冲声管中测试了合成试样的声压反射系数和吸声系数,研究了不同扩链剂及不同含量的2,6-二叔丁基-4-甲基苯酚(BHT)对其水下声学性能的影响。测试结果表明:TDI-PPG-MOCA合成型聚氨酯是一种良好的水下透声材料,TDI-PPG-TMP合成型聚氨酯是一种良好的水下吸声材料;BHT的加入对TDI-PPG-TMP合成型聚氨酯的水下吸声性能有显著提高,因此合理地设计实验工艺参数,可以得到水下声学性能更佳的聚氨酯。     

双波段夹层天线罩平板的应用研究

以5层天线罩材料平板为例,利用数值分析技术研究了其宽带透波性能.给出了确定多层天线罩材料宽带透波性能的优化方法.以此为依据,分析了3层平板材料(A夹层)和5层平板材料(C夹层)在微波波段(C波段)和毫米波波段(Ka波段)的透波性能.为多层天线罩材料双波段透波性能设计提供了一种技术手段.     

步兵轻武器新型夜瞄复合荧光材料的性能研究

采用自制的复合荧光粉体和化学载体成分,研制出一种步兵轻武器新型夜瞄复合荧光材料.通过试验分别研究了新材料的发光性能、耐温性能、耐腐蚀性能和耐表面处理性能.试验结果表明,研制的新型夜瞄复合荧光材料发光时间长、亮度高,具有良好的耐温、耐腐蚀性能,不受武器表面处理的影响,可满足步兵轻武器夜间瞄准需求.     

Reaction characteristic of PTFE/Al/Cu/Pb composites and application in shaped charge liner

In this paper, the reaction characteristic and its application in shaped charge warhead of a novel reactive material, which introduced copper (Cu) and plumbum (Pb) into traditional polytetrafluoroethylene/aluminum (PTFE/Al), are studied. The thermal analysis and chemical reaction behavior of the PTFE/Al/Cu/Pb mixture are investigated by Differential Scanning Calorimetry (DSC),Thermo-gravimetry (TG), and X-ray Diffraction (XRD) techniques. Then, the shaped charge liners with PTFE/Al/Cu/Pb reactive materials are fabricated, and the X-ray experiments show that they could form reactive jets with excellent performance under the detonation effects of the shaped charge. Based on that, the penetration experiments of shaped charge with PTFE/Al/Cu/Pb reactive liner against steel plates are carried out, and the results demonstrate that the PTFE/Al/Cu/Pb reactive jets could produce a deeper penetration depth compared to the traditional PTFE/Al reactive jets. Meanwhile, the PTFE/Al/Cu/Pb reactive jets also show significant inner-blast effects, leading to dramatically cracking or fragmentation behavior of the penetrated steel plates. This new PTFE/Al/Cu/Pb reactive liner shaped charge presents enhanced penetration behavior for steel targets that incorporates the penetration capability of a high-density and ductility jet, and the chemical energy release of PTFE-matrix reactive materials.     

Shock-induced reaction behaviors of functionally graded reactive material

In this paper, the ballistic impact experiments, including impact test chamber and impact double-spaced plates, were conducted to study the reaction behaviors of a novel functionally graded reactive material (FGRM), which was composed of polytetrafluoroethylene/aluminum (PTFE/Al) and PTFE/Al/bismuth trioxide (Bi₂O₃). The experiments showed that the impact direction of the FGRM had a significant effect on the reaction. With the same impact velocity, when the first impact material was PTFE/Al/Bi₂O₃, compared with first impact material PTFE/Al, the FGRM induced higher overpressure in the test chamber and larger damaged area of double-spaced plates. The theoretical model, which considered the shock wave generation and propagation, the effect of the shock wave on reaction efficiency, and penetration behaviors, was developed to analyze the reaction behaviors of the FGRM. The model predicted first impact material of the FGRM with a higher shock impedance was conducive to the reaction of reactive materials. The conclusion of this study provides significant information about the design and application of reactive materials.     

The effect of sintering and cooling process on geometry distortion and mechanical properties transition of PTFE/Al reactive materials

In this research, the effect of the sintering and cooling process on geometry distortion and mechanical properties of PTFE/Al reactive material is investigated. Six particularly selected sintering temperatures, three different cooling modes (annealing cooling, normalizing cooling and rapid cooling), three different initial cooling temperatures, as well as six different final cooling temperatures were designed to compare the effects of sintering temperature, cooling rate, initial cooling temperature and final cooling temperature on the properties of reactive materials. Geometry distortion was quantitatively analyzed by a statistic on the dimensional changes of the specimens and microscopic morphology. A mechanical response properties transition from brittle to ductile was found and analyzed. By combining the thermodynamic properties of PTFE and unsteady heat conduction theory, mechanisms of cooling induced morphology change, temperature induced distortion and strength decrease were obtained. The results showed that the cooling rate has the most significant effect on the morphology transformation, while initial cooling temperature has more significant effect on the dimensional distortion than final cooling temperature. As to the mechanical properties transition from brittle to plastic, a more prominent effect of initial cooling temperature than cooling rate and final temperature was revealed.     

Investigation of the shock compression behaviors of Al/PTFE composites with experimental and a 3D mesoscale-model

The responses of AI/PTFE reactive materials (RMs) under shock compression were investigated by a single-stage gas gun.A 3D mesoscale-model was established based on micro-computed tomography(micro-CT) slice images and confirmed with experimental results.In the high-pressure stage,the com-posites reacted partially,whereas there were no deviations between the partially reacted Hugoniot and the inert simulation results.The simulation reveals that the Teflon matrix melting on the high shock pressure.Melts and decomposition of the PTFE accelerated the diffusion of the atoms.Thus,the reactions of the Al/PrFE composites are more like a combustion rather than a detonation.     

The effect of al particle size on thermal decomposition,mechanical strength and sensitivity of Al/ZrH2/PTFE composite

To study the thermal decomposition of Al/ZrH2/PTFE with different Al particle size as well as mechanical strength and impact sensitivity under medium and low strain rates, molding-vacuum sintering was adopted to prepare four groups of power materials and cylindrical specimens with different Al particle size. The active decomposition temperature of ZrH2 was obtained by TG-DSC, and the quasi-static me-chanics/reaction characteristics as well as the impact sensitivity of the specimen were studied respec-tively by quasi-static compression and drop-hammer test. The results show that the yield strength of the material decreased with the increase of the Al particle size, while the compressive strength, failure strain and toughness increased first and then decreased, which reached the maximum values of 116.61 MPa, 191％, and 119.9 MJ/m respectively when the Al particle size is 12—14μm because of particle size grading. The specimens with the highest strength and toughness formed circumferential open cracks and reacted partly when pressed. Those with developmental cracks formed inside did not react. It is considered that fracture of specimens first triggered initial reaction between Al and PTFE to release an amount of heat. Then ZrH2 was activated and decomposed, and participated in subsequent reaction to generate ZrC. The impact sensitivity of the specimens decreased with the increase of Al particle size.     

通孔与闭孔泡沫铝水下隔声性能实验研究

对空气饱和与水饱和两种情况下的通孔泡沫铝以及闭孔泡沫铝开展了水下隔声性能实验研究。实验结果表明:在[500,4 000]Hz范围内,水饱和通孔泡沫铝和闭孔泡沫铝具有良好的隔声性能,而空气饱和通孔泡沫铝水下隔声性能相对较弱。与现有橡胶类水声去耦材料相比,水饱和通孔泡沫铝具有良好的低频、宽带隔声特性以及耐压且不受温度的影响等特点,可以作为一种潜在的性能优良的水声去耦材料。     

Nanothermite colloids: A new prospective for enhanced performance

Nanothermites (metal oxide/metal) can offer tremendously exothermic self sustained reactions. CuO is one of the most effective oxidizers for naonothermite applications. This study reports on two prospectives for the manufacture of CuO nanoparticles. Colloidal CuO particles of 15 nm particle size were developed using hydrothermal synthesis technique. Multiwalled carbon nanotubes (MWCNTs) with surface are 700 m²/g was employed as a substrate for synthesis of CuO-coated MWCNTs using electroless plating. On the other hand, aluminium particles with combustion heat of 32000 J/g is of interest as high energy density material. The impact of stoichiometric nanothermite particles (CuO/Al & Cuo-coated MWCNTs/Al) on shock wave strength of Al/TNT nanocomposite was evaluated using ballistic mortar test. While CuO-coated MWCNTs decreased the shock wave strength by 15%; colloidal CuO enhanced the shock wave strength by 30%. The superior performance of colloidal CuO particles was correlated to their steric stabilization with employed organic solvent. This is the first time ever to report on fabrication, isolation, and integration of stablilized colloidal nanothermite particles into energetic matrix where intimate mixing between oxidizer and metal fuel could be achieved.     

Chain damage effects of multi-spaced plates by reactive jet impact

Chain damage is a new phenomenon that occurs when a reactive jet impacts and penetrates multi-spaced plates.The reactive jet produces mechanical perforations on the spaced plates by its kinetic energy(KE),and then results in unusual chain rupturing effects and excessive structural damage on the spaced plates by its deflagration reaction.In the present study,the chain damage behavior is initially demonstrated by experiments.The reactive liners,composed of 26 wt％Al and 74 wt％PTFE,are fabricated through a pressing and sintering process.Three reactive liner thicknesses of 0.08 CD,0.10 CD and 0.12 CD(charge diameter)are chosen to carry out the chain damage experiments.The results show a chain rupturing phenomenon caused by reactive jet.The constant reaction delay time and the different penetration velocities of reactive jets from liners with different thicknesses result in the variation of the deflagration position,which consequently determines the number of ruptured plates behind the armor.Then,the finite-element code AUTODYN-3D has been used to simulate the kinetic energy only-induced rupturing effects on plates,based on the mechanism of behind armor debris(BAD).The significant discrepancies between simulations and experiments indicate that one enhanced damage mechanism,the behind armor blast(BAB),has acted on the ruptured plates.Finally,a theoretical model is used to consider the BAB-induced enhancement,and the analysis shows that the rupturing area on aluminum plates depends strongly upon the KE only-induced pre-perforations,the mass of reactive materials,and the thickness of plates.     

低Ni/改性Al2O3催化剂表面性质表征

本文用氧吸附法和程序升温脱附（ＴＰＤ）法分别考察低Ｎｉ／改性Ａｌ２Ｏ３催化剂的分散度，环已烷和苯的吸附脱附性能。结果表明：该催化剂分散性好，表面至少存在两种吸附中心。苯、环已烷在该催化剂的表面上属于一级可逆吸附脱附过程，催化剂表面能量分布不均匀。     

Experimental investigation on enhanced damage to fuel tanks by reactive projectiles impact

Enhanced damage to the full-filled fuel tank,impacted by the cold pressed and sintered PTFE/AL/W reactive material projectile(RMP)with a density of 7.8 g/cm3,is investigated experimentally and theoretically.The fuel tank is a rectangular structure,welded by six pieces of 2024 aluminum plate with a thickness of 6 mm,and filled with RP-3 aviation kerosene.Experimental results show that the kerosene is ignited by the RMP impact at a velocity above 1062 m/s,and a novel interior ignition phenomenon which is closely related to the rupture effect of the fuel tank is observed.However,the traditional steel projectile with the same mass and dimension requires a velocity up to 1649 m/s to ignite the kerosene.Based on the experimental results,the radial pressure field is considered to be the main reason for the shear failure of weld.For mechanism considerations,the chemical energy released by the RMP enhances the hydrodynamic ram(HRAM)effect and provides additional ignition sources inside the fuel tank,thereby enhancing both rupture and ignition effects.Moreover,to further understand the enhanced ignition effect of RMP,the reactive debris temperature inside the kerosene is analyzed theoretically.The initiated reactive debris with high temperature provides effective interior ignition sources to ignite the kerosene,resulting in the enhanced ignition of the kerosene.