研究羟基端聚丁二烯基能复合材料的热分解动力学和热力学参数

P. Kishore, Arjun Singh, Rajesh Kumar, P. Thakur, P. Soni, A. Thakur
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To\nunderstand the stability and safety of energetic composites for potential applications, it\nis necessary to understand the thermal decomposition kinetics and thermodynamic parameters\nclearly.\n\n\n\nThe main objective is to study the decomposition kinetic and thermodynamic\nparameters of energetic composites cured by different curing agents.\n\n\n\nA series of energetic composites based on HMX (1,3,5,7-tetranitro-1,3,5,7-\ntetrazocane) and HTPB-based binder system cured with various curing agents were\nprepared by the cast cured method. The curatives, namely MDI (4,4’-methylene diphenyl\ndiisocyanate), IPDI (isophorone diisocyanate), TDI (toluene dissocyanate) and\nTMDI (2,2,4-trimethylhexamethylene diisocyanate) were used. The thermal analysis\nmethod was employed to investigate the thermal decomposition characteristics, which\nare closely associated with the thermal stability and safety considerations during handling,\nprocessing, and storage. The kinetic parameters for thermal decomposition reactions\nwere studied by employing the Flynn-Wall-Ozawa method. The thermodynamic\nparameters of the activation enthalpy, activation Gibbs energy free and activation entropy\nof all energetic composites were also determined by the theory of activated complex.\n\n\n\nThe thermogravimetric results show that the thermal stability is almost similar\nfor all composites cured with the different types of curing agents. The average activation\nenergy of the energetic composites cured with IPDI, MDI, TMDI and TDI was 207.5,\n237.3, 243.3 and 187.6 kJ/mol, respectively. The thermodynamic parameters for the thermal\ndecomposition process show that they are generally thermodynamically stable and\nnon-spontaneous. Scanning electron microscope (SEM) micrographs of all the samples\nclearly indicate that HMX crystals are well embedded in the polymer matrices.\n\n\n\nThe thermogravimetric results show that the thermal stability and thermal decomposition behaviour do not change significantly by varying the type of the curing agent in the HTPB-based binder. The SEM micrographs of all the samples clearly indicate that HMX crystals are well embedded in the polymer matrices. The averaged activation energy for the HMX/HTPB/MDI, HMX/HTPB/IPDI, HMX/HTPB/TDI and HMX/HTPB/TMDI samples obtained from FO method was 237.3, 207.5, 187.6 and 243.3 kJ/mol, respectively. The thermodynamic parameters including the activation enthalpy, activation Gibbs free energy and activation entropy for the thermal decomposition process show that they are generally thermodynamically stable and non-spathaceous.\n\n\n\nThe thermal stability of all energetic composites is almost constant. 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引用次数: 0

摘要

基于羟基端聚丁二烯(HTPB)的高能复合材料已被开发用于增强爆炸高能复合材料、复合火箭推进剂配方、金属切割、爆破、焊接以及民用和军用爆炸装甲。固化剂的类型和选择对于提高粘结剂的机械和结构完整性至关重要。为了了解潜在应用中的高能复合材料的稳定性和安全性,有必要清楚地了解其热分解动力学和热力学参数。本研究采用浇注固化法制备了一系列基于 HMX(1,3,5,7-四硝基-1,3,5,7-四氮杂环丁烷)和 HTPB 基粘结剂体系的高能复合材料。固化剂包括 MDI(4,4'-亚甲基二苯基二异氰酸酯)、IPDI(异佛尔酮二异氰酸酯)、TDI(甲苯二异氰酸酯)和 TMDI(2,2,4-三甲基六亚甲基二异氰酸酯)。热分析法用于研究热分解特性,这些特性与热稳定性以及处理、加工和储存过程中的安全考虑密切相关。采用 Flynn-Wall-Ozawa 方法研究了热分解反应的动力学参数。热重结果表明,使用不同类型固化剂固化的所有复合材料的热稳定性几乎相似。用 IPDI、MDI、TMDI 和 TDI 固化的高能复合材料的平均活化能分别为 207.5、237.3、243.3 和 187.6 kJ/mol。热分解过程的热力学参数表明,它们在热力学上基本稳定,且不自发。所有样品的扫描电子显微镜(SEM)显微照片都清楚地表明,HMX 晶体很好地嵌入了聚合物基质中。热重结果表明,热稳定性和热分解行为不会因 HTPB 基粘合剂中固化剂类型的不同而发生显著变化。所有样品的扫描电镜显微照片都清楚地表明,HMX 晶体很好地嵌入了聚合物基质中。通过 FO 方法获得的 HMX/HTPB/MDI、HMX/HTPB/IPDI、HMX/HTPB/TDI 和 HMX/HTPB/TMDI 样品的平均活化能分别为 237.3、207.5、187.6 和 243.3 kJ/mol。热分解过程中的热力学参数(包括活化焓、活化吉布斯自由能和活化熵)表明,它们在热力学上基本稳定,且无空间分布。制备的高能复合材料的活化能随 HTPB 基粘结剂体系中固化剂类型的不同而显著变化。扫描电镜显微照片表明,制备的复合材料中的 HMX 晶体嵌入聚合物基体中。
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Investigating Thermal Decomposition Kinetics and Thermodynamic Parameters of Hydroxyl-Terminated Polybutadiene-based Energetic Composite
Hydroxyl-Terminated Polybutadiene (HTPB)-based energetic compositions have been developed for enhanced blast energetic composite, composite rocket propellant formulations, metal cutting, demolition, welding and explosive reactive armour in civil and military applications. The types and choice of curing agents are crucial in enhancing the mechanical and structural integrity of the binder. To understand the stability and safety of energetic composites for potential applications, it is necessary to understand the thermal decomposition kinetics and thermodynamic parameters clearly. The main objective is to study the decomposition kinetic and thermodynamic parameters of energetic composites cured by different curing agents. A series of energetic composites based on HMX (1,3,5,7-tetranitro-1,3,5,7- tetrazocane) and HTPB-based binder system cured with various curing agents were prepared by the cast cured method. The curatives, namely MDI (4,4’-methylene diphenyl diisocyanate), IPDI (isophorone diisocyanate), TDI (toluene dissocyanate) and TMDI (2,2,4-trimethylhexamethylene diisocyanate) were used. The thermal analysis method was employed to investigate the thermal decomposition characteristics, which are closely associated with the thermal stability and safety considerations during handling, processing, and storage. The kinetic parameters for thermal decomposition reactions were studied by employing the Flynn-Wall-Ozawa method. The thermodynamic parameters of the activation enthalpy, activation Gibbs energy free and activation entropy of all energetic composites were also determined by the theory of activated complex. The thermogravimetric results show that the thermal stability is almost similar for all composites cured with the different types of curing agents. The average activation energy of the energetic composites cured with IPDI, MDI, TMDI and TDI was 207.5, 237.3, 243.3 and 187.6 kJ/mol, respectively. The thermodynamic parameters for the thermal decomposition process show that they are generally thermodynamically stable and non-spontaneous. Scanning electron microscope (SEM) micrographs of all the samples clearly indicate that HMX crystals are well embedded in the polymer matrices. The thermogravimetric results show that the thermal stability and thermal decomposition behaviour do not change significantly by varying the type of the curing agent in the HTPB-based binder. The SEM micrographs of all the samples clearly indicate that HMX crystals are well embedded in the polymer matrices. The averaged activation energy for the HMX/HTPB/MDI, HMX/HTPB/IPDI, HMX/HTPB/TDI and HMX/HTPB/TMDI samples obtained from FO method was 237.3, 207.5, 187.6 and 243.3 kJ/mol, respectively. The thermodynamic parameters including the activation enthalpy, activation Gibbs free energy and activation entropy for the thermal decomposition process show that they are generally thermodynamically stable and non-spathaceous. The thermal stability of all energetic composites is almost constant. The activation energy of the prepared energetic composites is significantly varied with varying the type of curing agents in the HTPB-based binder system. The thermodynamic parameters indicate that composites possess superior stability and thermal safety. The SEM micrographs indicate that HMX crystals of prepared composites are embedded in the polymer matrix.
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来源期刊
Current Materials Science
Current Materials Science Materials Science-Materials Science (all)
CiteScore
0.80
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0.00%
发文量
38
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