Mg2NiH4对高氯酸铵热分解过程的影响

采用置换-扩散法制备了储氢材料Mg2NiH4, 用XRD, ICP和DSC-TG方法对其结构进行了表征. 用热分析法(DSC)研究了Mg2NiH4对高氯酸铵(AP)热分解过程的影响. 研究结果表明, Mg2NiH4对AP热分解过程有较大影响. Mg2NiH4可以显著促进AP的低温热分解过程, 降低高温热分解温度, 使DSC表观分解热明显增大. 随着加入量的增加, Mg2NiH4对AP热分解的催化促进作用增强, 当Mg2NiH4加入的质量分数为30％时, DSC表观分解热最大. 吸氢量越大, 储氢材料对AP的催化促进作用越强. Mg2NiH4催化促进AP分解过程的作用机理为: Mg2NiH4分解释放的H2及Mg和Ni与AP分解产物发生反应.     

铝粉粒度对高氯酸铵热分解动力学的影响

采用热重-差示扫描量热(TG-DSC)联合技术研究了10.7 μm, 2.6 μm和40 nm铝粉对高氯酸铵(AP)热分解的影响. 结果表明, 铝粉的加入对AP的低温放热峰有抑制作用, 对高温放热分解反应有促进作用, 并且随铝含量的增加和铝粒径的减小这种作用更强烈. 采用多元非线性拟合技术对不同升温速率下TG-DSC实验数据进行拟合, 结果表明, 质量分数为40%的不同粒径铝粉的加入对AP的热分解三阶段(A→B→C→D)反应模型无影响, 但反应机理函数发生了改变. 纯AP, AP/Al(10.7 μm), AP/Al(2.6 μm)及AP/Al(40 nm)的反应机理函数组合分别为C1/D1/D1, C1/D1/D3, C1/D1/D4和C1/D1/F2.     

纳米铜粉对高氯酸铵热分解的影响

The decomposition behaviour of ammonium perchlorate (AP) has been investigated in the presence of Cu nanopowder by DTA. The results show that nanometer Cu powder decreased the first and second thermal decomposition temperature of AP by 35.1 ℃ and 130.2 ℃, respectively, and the DTA heat release of AP in the presence of Cu nanopowders increased to 1.20 kJ·g^-1, showing good catalytic effect on the thermal decomposition of AP. The catalytic effect of Cu micron-size powder on the thermal decomposition of AP was less than that of Cu nanopowder. With the increase in content, Cu nanopowder enhanced its catalytic effect on the high temperature decomposition of AP, however, it weakened its catalytic effect on the low temperature decomposition of AP. The mechanism of catalysis for the thermal decomposition of AP is as follows: (1) metal oxider acts as the intermedium in the process of election tranfer, (2) Cu nanopowder reacts with the decomposed product of AP, (3) Cu nanopowder has special surface effect.     

镁基复合储氢材料

镁基储氢材料以其低成本，高能量密度，引起人们的广泛关注，本文简要介绍了镁基复合储氢材料的最新进展。     

纳米金属粉对高氯酸铵热分解动力学的影响

The thermal decomposition characteristics of general ammonium perchlorate (g-AP) influenced by the addition of aluminum, nickel with different particle sizes (general and nano) are studied by TG and DSC. The results show that aluminum powders (both general and nano size) are nearly uninfluenced. Nano nickel powders have the greatest influence on the decomposition properties of g-AP among metal powders. Such accelerating effects of nanonickel powders are more apparent on the stage of high temperature decomposition than low temperature decomposition of g-AP and will be weakened with the decrease of the content of nanonickel. Nanonickel powders are also more effective than super fine nickel powders on accelerating the thermal decomposition of superfine AP (s-AP). The kinetic parameters of the thermal decomposition of s-AP and mixture of s-AP and nano nickel powders are obtained from the TG-DTG curves bythe integral method based on the Coats-Red fern equation. Nanonickel powders reduce the apparent activation energy of the thermal decomposition of s-AP from 157.9 kJ/mol to 134.9 kJ/mol. The most probable mechanism functions of the thermal decomposition reaction for s-AP and mixture of s-AP and nano nickel powders both belong to systems of Avrami-Erofeev equations. The mechanism of such accelerating effects has been discussed.     

纳米Cu2O的制备及其对高氯酸铵热分解的催化性能

 以Cu(NO3)2和NaOH为原料,以水合肼为还原剂,通过沉淀法在室温下制备了纳米Cu2O. 采用X射线衍射、透射电镜和X射线光电子能谱等手段对产物进行了表征,并用热分析法考察了不同形貌的纳米Cu2O对高氯酸铵热分解的催化作用. 结果表明,通过改变NaOH溶液的加入量可分别得到长针形和多边形的纳米Cu2O. 通过调节反应物浓度可以将纳米Cu2O粒径控制在19～68 nm. 不同形貌的纳米Cu2O均能强烈催化高氯酸铵的热分解,其中分散性良好的多边形纳米Cu2O的催化活性较高,添加2%的多边形纳米Cu2O可使高氯酸铵的高温分解温度降低103 ℃,分解放热量由590 J/g增至1350 J/g.     

纳米金属粉对高氯酸铵热分解特性的影响

催化性能;纳米金属粉对高氯酸铵热分解特性的影响     

草酸钴原位催化高氯酸铵热分解的DSC／TG-MS研究

采用差示扫描量热/热分析-质谱(DSC/TG-MS)联用技术研究了草酸钴对高氯酸铵的原位催化. 结果表明,草酸钴原位分解生成的钴氧化物对高氯酸铵有较强的催化作用,添加2%的草酸钴使高氯酸铵的分解温度降低104 ℃, 分解放热量从655 J/g增大到 1 469 J/g. 分解的气相产物主要有H2O, NH3,O2,HCl,Cl2,NO,N2O和NO2. 由于氧在新生态的纳米钴氧化物表面形成过氧化活性离子(O-2), 使氨氧化在钴氧化物的过氧化表面活性中心进行,加速了高氯酸铵的热分解,使其表观放热量大幅度增加.     

不同粒度高氯酸铵的热分解研究

利用高压差示扫描量热法(PDSC), 热重法(TG), 固体原位红外联用法(Thermolysis/RSFT-IR)和热分析与质谱和红外联用法(Thermal analysis-MS-FTIR)研究了不同粒度高氯酸铵AP在1.0 MPa压强下和常压下的热分解过程, 提出了不同粒度AP可能的热分解机理. 研究结果表明, 不同粒度AP的高压和常压下的热分解历程存在明显的差异, 较大粒度AP的受热分解过程中存在明显的低温分解阶段和高温分解阶段, 小粒度的AP则仅存在明显的高温分解阶段. AP的分解气体产物主要包括NO2, NO, N2O, O2, H2O和HCl.     

镁基储氢材料研究新进展

综述了近几年镁基储氢材料研究的最新进展,总结了目前改善镁基储氢材料性能所用的主要方法,例如反应机械合金化、氢化燃烧合成、掺杂催化元素、制备复合材料、组元替代等。指出采用反应机械合金化法、储氢合金组元调整以及添加催化剂是改善性能最有效的途径。     

纳米Co-B非晶态合金对高氯酸铵分解的催化性能

 利用化学还原法制备了纳米 Co-B 非晶态合金,并用透射电镜、X射线衍射、差示扫描量热和N2吸附表面积测试等技术对样品进行了表征. 运用差热分析研究了纳米 Co-B 非晶态合金对高氯酸铵(AP)分解的催化性能. 结果表明,加入 Co-B 非晶态合金后AP的高低温放热峰相连,合并成一个高而大的放热峰,且峰温有很大程度的降低, 这说明纳米 Co-B 非晶态合金对AP热分解有很好的催化活性. 同时, Co-B 非晶态合金能使AP的表观分解热显著增大.     

纳米Co3O4的制备及其对高氯酸铵热分解的催化性能

 选用CoCl2·6H2O分别与NaOH, H2C2O4·2H2O, Na2CO3·10H2O及Na2C2O4组成四个反应体系,通过室温固相反应制备了不同平均粒径的纳米Co3O4, 并用X射线衍射和透射电镜对Co3O4的物相、形貌和粒径大小进行了表征. 结果表明, Co3O4的平均粒径分别为23, 30, 35和150 nm, 大小均匀,分散性好. 还用差热分析法考察了纳米Co3O4对高氯酸铵热分解的催化性能,并与微米Co3O4进行了比较. 结果表明,纳米Co3O4可使高氯酸铵的低温放热峰消失,高温放热峰温度降至323.5 ℃, 降低了128.5 ℃, 表观分解热增加了750 J/g, 达 1265 J/g, 纳米Co3O4对高氯酸铵热分解的催化性能明显好于微米Co3O4.     

Preparation of Ni/TiO2 Nanoparticles and Their Catalytic Performance on the Thermal Decomposition of Ammonium Perchlorate

Metal/oxide nanoparticles are attractive because of their special structure and better properties. The Ni/TiO₂ nanoparticles were prepared by a liquid phase chemical reduction method in this paper. The obtained‐products were characterized by inductively coupled plasma (ICP), X‐ray diffraction (XRD), high‐resolution transmission electron microscopy (HRTEM) and scanning electron microscopy (SEM). The results show that Ni particles in Ni/TiO₂ nanoparticles exhibit better dispersion and the size of most Ni particles is 10 nm or so. The catalytic activity of Ni/TiO₂ nanoparticles on the thermal decomposition of ammonium perchlorate (AP) was investigated by simultaneous thermogravimetry and differential thermal analysis (TG‐DTA). Results show that composite process of Ni and TiO₂ can improve the catalytic activity of Ni nanoparticles on the thermal decomposition of AP, which is mainly attributed to the improvement of Ni dispersion in Ni/TiO₂ nanoparticles. The catalytic activity of Ni/TiO₂ nanoparticles increases with increasing the weight ratio of Ni to AP.     

双核茂铁四氮唑的合成及对高氯酸铵热分解的催化作用

首先以二茂铁为原料合成丙基桥联的双聚二茂铁(DFP), 经甲酰化得到丙基桥联的双聚二茂铁甲醛(DFP-CHO, 1), 再与NH₂OH·5HCl进行缩合反应得到双核二茂铁肟(2), 然后脱水得到丙基桥联双聚二茂铁甲腈(3), 最后在(n-C₄H₉)₃SnCl 的催化作用下与NaN₃进行[2+3]环加成反应, 生成目标产物丙基桥联双聚二茂铁四唑(4); 通过¹H NMR, FTIR和ESI-MS对目标产物的结构进行了表征. 利用差示扫描量热分析(DSC)和热重(TG)分析研究了这2个双聚二茂铁氮杂衍生物的燃速催化性能, 结果表明, 通过添加质量分数为5%的丙基桥联双聚二茂铁氮杂化合物3和4均使高氯酸铵(AP)的热分解温度降至100℃左右.     

纳米Fe2O3的制备及其对高氯酸铵热分解的催化性能

 用两相体系方法制备了纳米Fe2O3，并用X射线衍射、红外光谱和粒度分析对其结构进行了表征．结果表明，当有机溶胶的pH＝6，油酸与Fe3＋的摩尔比为1∶3．5时，Fe（OH）3在油相中的萃取率可高达90％，将有机溶胶在120℃回流8h后可得到非晶态、窄粒度分布的纳米Fe2O3粒子，其粒径在12nm左右．分别采用恒容燃烧热和差热分析研究了纳米Fe2O3对高氯酸铵热分解的催化性能．结果表明，在模拟固体推进剂中分别加入4．7％微米Fe2O3和4．7％纳米Fe2O3后，恒容燃烧热分别提高了2350．84和5095．70J／g．在高氯酸铵中加入5％微米Fe2O3可使高氯酸铵两个放热峰的出现分别提前1．10和62．25℃，而加入5％纳米Fe2O3时分别提前61．89和118．82℃，这说明纳米Fe2O3的催化活性优于微米Fe2O3．     

Effects of Aluminum on Thermal Decomposition of Hexogen/Ammonium Perchlorate

Thermogravimetry-differential scanning calorimetry-mass spectrometry-Fourier transform infrared spectrometry（TG-DSC-MS-FTIR） simultaneous analysis was used to study the effects of 10.7 μm and 40 nm Al on the thermal decomposition of the Hexogen/ammonium perchlorate（RDX/AP,1/2,mass ratio） mixture.TG-DSC results show that there are two mass loss processes for the thermal decomposition of RDX/AP/Al.The first one is mainly ascribed to the thermal decomposition of RDX.The reaction rate of RDX/AP/10.7 μm Al is so fast that the apparent activation energy,calculated by model-free Friedman method,is negative,which is the same as that of RDX/AP.30％（mass fraction） 40 nm Al added in RDX/AP change the activation energy from negative to positive value.The second mass loss process of the RDX/AP/A1 mixture is ascribed to the thermal decomposition of AP.This process can be divided into three stages for RDX/AP with and without Al.The kinetics model is not changed in the presence of micro-sized Al,while it is changed from CnB/D1/D1 to CnB/D1/D4 after the addition of 40 nm Al to RDX/AP.The reaction rate constant of the first stage and the end temperature of the second stage decrease,while the end temperatures of the third stage increase in the presence of 40 nm Al.The MS-FTIR results show there is a competition between the formation reactions of HNCO,N2O and NO2 during the second mass loss process.