Application and development trend of microfluidic technology in the preparation of energetic materials

被引：0

作者：

Yu J. ^{[1
]}

Xu S.-Y. ^{[1
]}

Jiang H. ^{[1
]}

Zhao F. ^{[1
]}

机构：

[1] Xi'an Modern Chemistry Research Institute, Science and Technology on Combustion and Explosion Laboratory, Xi'an

来源：

Huozhayao Xuebao/Chinese Journal of Explosives and Propellants | 2022年 / 45卷 / 04期

关键词：

Applied Chemistry; cover; energetic materials; House; modified;

D O I：

10.14077/j.issn.1007-7812.202203034

中图分类号：

学科分类号：

摘要：

Based on the current research on microfluidic technology at home and abroad, the research progress of microfluidic technology in the synthesis of energetic compounds, modification of elemental energetic materials, and preparation of composite energetic materials is reviewed from the perspective of equipment and material performance regulation. Based on development needs, it is pointed out that in the future, we should focus on overcoming the blockage of microchannels and expand the application of solid-containing systems; combine flow field simulation to accurately select process parameters; further combine on-line detection technology to establish an automatic feedback adjustment system to realize intelligent preparation of energetic materials; High-throughput advantages, promote the application of microfluidic technology in the industrial production of energetic materials. 102 references are attached. © 2022 China Ordnance Industry Corporation. All rights reserved.

引用

页码：439 / 451

页数：12

共 102 条

[11]

ZOU Qian, Microfluidic one-step preparation of calcium alginate microspheres encapsulated with in situ-formed gold nanostars and their photothermal effect, (2018)

[12]

ZHOU Nan, Segmented flow synthesis and crystallization process of typical nitrophenol initiating explosives, (2016)

[13]

BECKER H., Polymer microfluidic devices, Talanta, 56, 2, pp. 267-287, (2002)

[14]

CHEN Meng-yue, HAO Xiu-qing, LI Zi-yi, Et al., Research progress on processing technology of microfluidic channels, Micronanoelectronic Technology, 58, 3, pp. 244-253, (2021)

[15]

TARANTO V, UELAND M, FORBES S L, Et al., The analysis of nitrate explosive vapour samples using Lab-on-a-chip instrumentation, J Chromatogr A, 1602, pp. 467-473, (2019)

[16]

PUMERA M, MERKOCI A, ALEGRET S., Chapter 35 microchip electrophoresis/electrochemistry systems for analysis of nitroaromatic explosives, Comprehensive Analytical Chemistry, 49, pp. 873-884, (2007)

[17]

WANG J, PUMERA M, COLLINS G, Et al., A chip-based capillary electrophoresis-contactless conductivity microsystem for fast measurements of low-explosive ionic components, The Analyst, 127, 6, pp. 719-723, (2002)

[18]

HU T, SANG W, CHEN K, Et al., Simple and sensitive colorimetric detection of a trace amount of 2,4,6-trinitrotoluene(TNT)with QD multilayer-modified microchannel assays, Materials Chemistry Frontiers, 3, 2, pp. 193-198, (2019)

[19]

CHARLES P T, WADHWA V, KOUYATE A, Et al., A high aspect ratio bifurcated 128-microchannel microfluidic device for environmental monitoring of explosives, Sensors, 18, 5, (2018)

[20]

CHARLES P T, DAVIS J, ADAMS A A, Et al., Multi-channeled single chain variable fragment(scFv)based microfluidic device for explosives detection, Talanta, 144, pp. 439-444, (2015)

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