嵌段聚氨酯弹性体的动态力学性能研究

以预聚体法合成了两嵌段聚醚—聚酯型聚氨酯弹性体。研究了配料比、氨酯基浓度及固化剂用量等对该体系动态力学性能的影响。发现:该嵌段共聚物是完全相容的,其玻璃化转变温度T_g与聚醚含量呈线性关系;固化剂用量对该体系的T_g亦有影响。此外,对于聚酯氨酯体系,其T_g值与氨酯基浓度U亦呈线性关系。     

■AB■_n型嵌段聚氨酯软硬段间的相容性与动态力学谱

本文讨论了■A—B■_n丢嵌段聚氨酯软硬段间的相容性对其动态力学谱(tanσ曲线)的影响,指出:相容性对tanσ曲线的影响的本质是相间过渡区的性质。对■A—B■_n型嵌段聚氨酯体系,当其由完全不相容向完全相容(或由完全相容向完全不相容)变化时,tanσ曲线形状的变化为窄→宽→窄。通过tanσ曲线的变化可定性分析其相容性变化。     

聚氨酯/环氧树脂SIN中的增塑作用初探

本文通过测量聚醚氨酯(PU)/环氧树脂(EP)SIN系列的玻璃化转变温度(Tg);并对该数据进行分析及用DiBenedetto理论式对该Tg数据进行了处理,发现PU/EP SIN中,EP对PU链段存在着较强的增塑作用,这个增塑作用与PU与EP网间的互穿作用并存,它主要受PU/EP组成配比等因素的影响。     

Preparation of ammonium nitrate-based solid composite propellants supplemented with polyurethane/nitrocellulose blends binder and their thermal decomposition behavior

To improve the performance of solid composite propellants (SCPs) supplemented with ammonium nitrate (AN) as an oxidizer, the incorporation of energetic ingredients such as explosives, energetic binders or catalysts is a common effective approach. For this purpose, polyurethane (PU), a typical inert binder, was mixed with nitrocellulose (NC) as an energetic polymer. Numerous composite solid propellant compositions based on AN and NC-modified polyurethane binder with different NC ratios were prepared. The prepared formulations were characterized using Fourier transform infrared spectroscopy (FTIR), RAMAN spectroscopy, X-ray diffraction (XRD), electron densimetry, thermogravimetric (TG) analysis, and differential scanning calorimetry (DSC). A kinetic study was then performed using the iterative Kissinger-Akahira-Sunose (It-KAS), Flynn-Wall-Ozawa (It-FWO), and non-linear Vyazovkin integral with compensation effect (VYA/CE) methods. The theoretical performances, such as theoretical specific impulse, adiabatic flame temperature, and ideal exhaust gaseous species, were also determined using the NASA Lewis Code, Chemical Equilibrium with Application (CEA). Spectroscopic examinations revealed the existence of NC and full polymerization of PU in the prepared propellants. According to density tests, the density of the propellant increases as the nitrocellulose component increases. According to the thermal analysis and kinetics study, the increase in NC content catalyzed the thermal decomposition of the AN-based composite solid propellants. Based on the theoretical study, increasing the amount of NC in the propellant increased the specific impulse and, as a result, the overall performance.