Study on Electrospray Formation of n-Al/PVDF CompositeParticles and Exothermic Properties

doi:10.13675/j.cnki. tjjs. 180567

Journal of Propulsion Technology ›› 2019, Vol. 40 ›› Issue (9): 2130-2136.DOI: 10.13675/j.cnki. tjjs. 180567

• Material,Propellant and Fuel • Previous Articles Next Articles

Study on Electrospray Formation of n-Al/PVDF CompositeParticles and Exothermic Properties

1.School of Chemical Engineering,Nanjing University of Science and Technology,Nanjing 210094，China;2.Unit 63961，The Chinese People’s Liberation Army,Beijing 100012，China

Published:2021-08-15

静电喷雾法制备n-Al/PVDF复合粒子及其放热性能研究

李亚宁¹,于宪峰²,郭婉肖¹,甘璐瑶¹,韩志伟¹,王伯良¹

1.南京理工大学化工学院;2.中国人民解放军63961部队，北京;100012

作者简介:李亚宁，博士生，研究领域为纳米含能材料的制备技术。E-mail：lyn_00446@163.com
基金资助:
国家自然科学基金 11702142;江苏省自然科学基金 BK20170825国家自然科学基金（11702142）；江苏省自然科学基金（BK20170825）。

Abstract

Abstract: Nano Al/PVDF composite particles with a core-shell structure were prepared by electrospray method. In order to optimize the formation parameters, including the inner diameter of the needle, the injection rate, the driving voltage, and the receiving distance, an orthogonal experiment was designed and carried out. Scanning electron microscopy (SEM), transmission electron microscopy (TEM), and differential scanning calorimetry (DSC) were employed to assess the morphology and the exothermic properties of the as-prepared composite particles. The results presented that the composite particles had best morphology in appearance produced in optimized conditions like a needle inner diameter 0.51mm, an injection rate 1mL/h, a receiving distance 10cm and a driving voltage 12kV. The composite particles had an average diameter 75nm which was in accordance with the raw n-Al powders. TEM results indicated that the PVDF coating was even whose thickness was around 5nm. According to DSC results, the sample in optimized conditions had the highest heat release both in N₂ atmosphere and air atmosphere. Moreover, the PVDF coating could significantly improve the energy release efficiency of n-Al powders resulting in much more aluminum oxidized.

Key words: n-Al/PVDF composite particles;Electrospray method;Nano particles;Orthogonal experiments;Exothermic properties

摘要： 采用静电喷雾法制备核壳结构纳米铝粉/聚偏二氟乙烯（n-Al/PVDF）复合粒子。为优化制备参数，设计了正交试验，利用扫描电子显微镜（SEM）、透射电子显微镜（TEM）、差示扫描量热仪（DSC）等设备研究了静电喷雾过程中针头内径、推进速率、输出电压、接收距离等4种因素对制备的复合粒子形貌和放热性能的影响。结果表明：在0.51mm针头内径，1mL/h推进速率，10cm接收距离，12kV输出电压条件下制备的复合粒子形貌最为规整，平均粒径为75nm，与原料n-Al颗粒基本一致；PVDF包覆层厚度均匀，平均厚度为5nm。DSC测试结果显示，按此条件制备的样品在惰性气氛及空气气氛条件下放热量最大，且均大于其他条件下制备的样品，PVDF包覆层能够显著改善n-Al粉末能量释放效率，使铝粉反应更完全。

关键词: n-Al/PVDF复合粒子;静电喷雾法;纳米粒子;正交试验;放热性能

LI Ya-ning¹,YU Xian-feng²,GUO Wan-xiao¹,GAN Lu-yao¹,HAN Zhi-wei¹,WANG Bo-liang¹. Study on Electrospray Formation of n-Al/PVDF CompositeParticles and Exothermic Properties[J]. Journal of Propulsion Technology, 2019, 40(9): 2130-2136.

李亚宁,于宪峰,郭婉肖,甘璐瑶,韩志伟,王伯良. 静电喷雾法制备n-Al/PVDF复合粒子及其放热性能研究[J]. 推进技术, 2019, 40(9): 2130-2136.

References

[1] Arkhipov V A, Korotkikh A G. The Influence of Aluminum Powder Dispersity on Composite Solid Propellants Ignitability by Laser Radiation[J]. Combustion and Flame， 2012， 159(1): 409-415.
[2] Galfetti L， DeLuca L T， Severini F， et al. Pre and Post-burning Analysis of Nano-Aluminized Solid Rocket Propellants[J]. Aerospace Science & Technology， 2007， 11(1): 26-32.
[3] Meda L， Marra G， Galfetti L， et al. Nano-Aluminum as Energetic Material for Rocket Propellants[J]. Materials Science & Engineering: C， 2007， 27(5-8): 1393-1396.
[4] Zhi J， Shu-Fen L， Feng-Qi Z， et al. Research on the Combustion Properties of Propellants with Low Content of Nano Metal Powders[J]. Propellants， Explosives， Pyrotechnics， 2006， 31(2): 139-147.
[5] 陈苏杭，唐乐，许志伟，等. 含铝HTPB固液混合推进燃料燃烧性能研究[J]. 推进技术， 2018， 39(6): 1412-1419.
[6] Mary Baptiste， Dubois Charles， Carreau Pierre J， et al. Rheological Properties of Suspensions of Polyethylene-coated Aluminum Nanoparticles[J]. Rheologica Acta， 2006， 45(5): 561-573.
[7] 刘松松，叶明泉，韩爱军，等. Al/HTPB含能复合粒子的制备及表征[J]. 含能材料， 2013， 21(6): 743-748.
[8] 郭连贵，宋武林，谢长生，等. 核壳结构纳米铝粉热学行为[J]. 推进技术， 2012， 33(3): 478-482.
[9] Li X， Guerieri P， Zhou W， et al. Direct Deposit Laminate Nanocomposites with Enhanced Propellent Properties[J]. ACS Applied Materials & Interfaces， 2015， 7(17): 9103-9109.
[10] Wang J， Qiao Z， Yang Y， et al. Core-Shell Al-Polytetrafluoroethylene (PTFE) Configurations to Enhance Reaction Kinetics and Energy Performance for Nanoenergetic Materials[J]. Chemistry， 2016， 22(1):279-284.
[11] Yang H. Characterization of Aluminum/Poly(Vinylidene Fluoride) by Thermogravimetric Analysis， Differential Scanning Calorimetry， and Mass Spectrometry[J]. Analytical Letters， 2015， 48(13): 2010-2021.
[12] Huang C， Jian G， Delisio J B， et al. Electrospray Deposition of Energetic Polymer Nanocomposites with High Mass Particle Loadings: A Prelude to 3D Printing of Rocket Motors[J]. Advanced Engineering Materials， 2015， 17(1): 95-101.
[13] AIAA. Ignition and Reaction Analysis of High Loading Nano-Al/Fluoropolymer Energetic Composite Films[C]. Maryland: 52nd Aerospace Sciences Meeting， 2014.
[14] 王江，李小东，王晶禹，等. 喷雾干燥法中溶剂对RDX颗粒形貌和性能的影响[J]. 含能材料， 2015， 23(3): 238-242.
[15] 王海洋. 纳米含能材料的静电喷雾法制备与燃烧特性表征[D]. 南京: 南京理工大学， 2015.

Study on Electrospray Formation of n-Al/PVDF CompositeParticles and Exothermic Properties

静电喷雾法制备n-Al/PVDF复合粒子及其放热性能研究

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