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含能增塑剂Bu-NENA与黏结剂共混体系的介观动力学模拟()

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《爆破器材》[ISSN:1001-8352/CN:32-1163/TJ]

卷:: 50
期数:: 2021年06

页码:: 8-13

栏目:: 基础理论

出版日期:: 2021-11-26

文章信息/Info

Title:: Mesoscopic Dynamics Simulation of Blends of Energetic Plasticizer Bu-NENA and Binder

文章编号:: 5586

作者:: 高杰; 金大勇; 郭昕; 牛磊; 西安近代化学研究所（陕西西安，710065）

Author(s):: GAO Jie; JIN Dayong; GUO Xin; NIU Lei; Xi’an Modern Chemistry Research Institute (Shaanxi Xi’an, 710065)

关键词:: 物理化学; Bu-NENA; HTPE; GAP; 相结构; 介观动力学模拟

Keywords:: physical chemistry; BuNENA; HTPE; GAP; phase structure; mesoscopic dynamics simulation

分类号:: TJ55

DOI:: 10.3969/j.issn.1001-8352.2021.06.002

文献标志码:: A

摘要:: 采用介观动力学（MesoDyn）模拟方法对比研究了含能增塑剂丁基硝氧乙基硝胺(Bu-NENA)与端羟基聚醚（HTPE）、聚叠氮缩水甘油醚（GAP）共混体系的相结构及其相演变过程和影响因素，用共混实验对Bu-NENA与HTPE、GAP的相容性进行了观察。模拟结果表明:Bu-NENA与HTPE、GAP均具有较好的混溶性，且Bu-NENA与HTPE的混溶性优于Bu-NENA与GAP，与混溶性实验的结果一致。25 ℃条件下，HTPE/Bu-NENA混合体系中Bu-NENA质量分数在50%以下时，HTPE和Bu-NENA混溶性较好；GAP/Bu-NENA混合体系中Bu-NENA质量分数在50%时，GAP和Bu-NENA的混溶性较其他比例时差。但在GAP/Bu-NENA 混合体系中，GAP和Bu-NENA的有序度参数P均较小，接近于0， GAP/Bu-NENA 混合体系混溶性良好；Bu-NENA 的质量分数对GAP/Bu-NENA 混合体系混溶性影响不大。

Abstract:: Phase structure, evolution process and influence factors of blends of energetic plasticizer Bu-NENA, and HTPE or GAP were studied by mesoscopic dynamics simulation (MesoDyn). Compatibility of Bu-NENA and HTPE or GAP was observed by blending test. Simulation results show that Bu-NENA has good miscibility with HTPE or GAP, and the miscibility of Bu-NENA and HTPE is better than that of Bu-NENA and GAP, which is consistent with the results of miscibility test. When mass fraction of Bu-NENA in HTPE/Bu-NENA blends is less than 50% at 25 ℃, the miscibility of HTPE and Bu-NENA is better. When mass fraction of Bu-NENA in GAP/Bu-NENA blends is 50% at 25 ℃, the miscibility of GAP and Bu-NENA is lower than that of other proportions. However, in GAP/Bu-NENA mixed system, the order parameter P?of GAP or Bu-NENA is small and close to zero, and the miscibility of GAP/Bu-NENA blend system is good. Mass fraction of Bu-NENA has little effect on the miscibility of Gap/Bu-NENA blend system.

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备注/Memo

备注/Memo:: 收稿日期：2021-03-09

基金项目：国防重大专项

第一作者：高杰（1986-），男，副研究员，主要从事炸药配方及装药技术研究。E-mail：njustgj@sina.com

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