Fluoropolymer/Glycidyl Azide Polymer (GAP) Block Copolyurethane as New Energetic Binders: Synthesis, Mechanical Properties, and Thermal Performance

Xu, Minghui; Lu, Xin; Liu, Ning; Zhang, Qian; Hu, Mo; Ge, Zhongxue

doi:10.3390/polym13162706

Cited by 10 publications

(8 citation statements)

References 51 publications

(50 reference statements)

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“…However, they are thermoset‐polymers that are often difficult to recycle. Furthermore, owing to the strong polarity of azide groups and the relatively inflexible nature of the polymer chain, they display both marked sensitivity and compromised mechanical characteristics 20–22 . To overcome these drawbacks and improve its performance, various azido‐based copolymers have been developed as binder for CSPs.…”

Section: Nitrogen‐rich Based Copolymer Bindersmentioning

confidence: 99%

Review on energetic copolymer binders for propulsion applications: Synthesis and properties

Touidjine

Boulkadid

Akbi

et al. 2023

Journal of Polymer Science

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This article aims to outline the current progress in the field of energetic copolymer binders for composite solid propellants (CSPs). Propellants, which are a type of energetic material, are used to generate thrust in rockets and missiles, and they are generally less sensitive than explosives. The common formulations of CSPs contain several different chemical compounds that are typically bound together by a polymeric matrix to form a continuous solid. The use of inert polymers, however, does not enhance the overall specific impulse of the propellant. Energetic copolymers have emerged as a compelling category of binders for CSPs in recent years, offering potential advantages over traditional binders such as improved performance, enhanced safety, and increased manufacturing efficiency. The paper reviews the various types of energetic copolymer binders that have been developed, their potential advantages and drawbacks, and the current challenges and opportunities in the field. It suggests directions for future research and development and aims to provide a useful resource for researchers and practitioners interested in the use of energetic copolymer binders toward CSPs.

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Section: Nitrogen‐rich Based Copolymer Bindersmentioning

confidence: 99%

Review on energetic copolymer binders for propulsion applications: Synthesis and properties

Touidjine

Boulkadid

Akbi

et al. 2023

Journal of Polymer Science

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“…Xu et al [ 64 ] reported an alternate type of GAP-based fluorinated polyurethane, synthesized by the copolymerization of GAP and 3,3-bis(2,2,2-trifluoroethoxymethyl) oxetane] glycol (BFMO) using toluene diisocyanate (TDI) as the crosslinker ( Scheme 4 ).…”

Section: Reactive Structures Based On Fluoropolymer-based Bindersmentioning

confidence: 99%

Nanoenergetic Composites with Fluoropolymers: Transition from Powders to Structures

2022

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Over the years, nanoenergetic materials have attracted enormous research interest due to their overall better combustion characteristics compared to their micron-sized counterparts. Aluminum, boron, and their respective alloys are the most extensively studied nanoenergetic materials. The majority of the research work related to this topic is confined to the respective powders. However, for practical applications, the powders need to be consolidated into reactive structures. Processing the nanoenergetic materials with polymeric binders to prepare structured composites is a possible route for the conversion of powders to structures. Most of the binders, including the energetic ones, when mixed with nanoenergetic materials even in small quantities, adversely affects the ignitability and combustion performance of the corresponding composites. The passivating effect induced by the polymeric binder is considered unfavorable for ignitability. Fluoropolymers, with their ability to induce pre-ignition reactions with the nascent oxide shell around aluminum and boron, are recognized to sustain the ignitability of the composites. Initial research efforts have been focused on surface functionalizing approaches using fluoropolymers to activate them further for energy release, and to improve the safety and storage properties. With the combined advent of more advanced chemistry and manufacturing techniques, fluoropolymers are recently being investigated as binders to process nanoenergetic materials to reactive structures. This review focuses on the major research developments in this area that have significantly assisted in the transitioning of nanoenergetic powders to structures using fluoropolymers as binders.

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“…Xu and coworkers [17] reported the synthesis of the fluorinated glycidyl azide polymer poly (2, 2, 2‐trifluoro‐ethoxymethyl epoxy‐ r ‐glycidyl azide), and the cook‐off test results indicated that the poly (TFEE‐ r ‐GA)/Al mixture gave a larger reaction energy than GAP/Al mixture. In another report from the same group, the fluorine‐containing polyurethanes of poly [3, 3‐bis (2, 2, 2‐trifluoro‐ethoxymethyl) oxetane] glycol‐block‐glycidyl azide polymer were synthesized, and the cook‐off test results also indicated that the PBFMO‐ b ‐GAP could enhance the energy release of the PBFMO‐ b ‐GAP/Al composites [18]. However, up to date, there have been very limited examples of energetic fluorine‐containing polymers, let alone a comprehensive understanding of their effect on the resultant energetic composites, including their basic properties, energy level and combustion, and so on.…”

Section: Introductionmentioning

confidence: 99%

High Performance Thermoplastic Energetic Composites Using Fluorinated Energetic Polyurethanes as Binder

Tang

Wang

chen³

et al. 2023

Propellants Explo Pyrotec

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The performance of energetic composite materials is largely dependent on the energy level and combustion process. The fluorine‐containing energetic polyurethanes as binder can facilitate the combustion of metallic fuels and enhance the energy level of the energetic composites. In the current report, two kinds of thermoplastic energetic composites are prepared, based on novel fluorine‐containing energetic polyurethanes as binder and also with aluminum nanoparticles (AlNPs) and ammonium perchlorate (AP). Compared with the energetic composites with fluorine‐free energetic polyurethane binder, despite the very low fluorine content, the fluorine‐containing energetic composites not only showed higher density, lower mechanical sensitivity, much higher mechanical toughness, but also a significantly improved combustion efficiency and combustion rate of the AlNPs.

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Fluoropolymer/Glycidyl Azide Polymer (GAP) Block Copolyurethane as New Energetic Binders: Synthesis, Mechanical Properties, and Thermal Performance

Cited by 10 publications

References 51 publications

Review on energetic copolymer binders for propulsion applications: Synthesis and properties

Review on energetic copolymer binders for propulsion applications: Synthesis and properties

Nanoenergetic Composites with Fluoropolymers: Transition from Powders to Structures

High Performance Thermoplastic Energetic Composites Using Fluorinated Energetic Polyurethanes as Binder

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