微流控纺丝技术及多元结构微流控纤维柔性可穿戴应用

张波; 胡希丽; 曲丽君

doi:10.13801/j.cnki.fhclxb.20221019.002

微流控纺丝技术及多元结构微流控纤维柔性可穿戴应用

doi: 10.13801/j.cnki.fhclxb.20221019.002

青岛大学　纺织服装学院，青岛 266071

基金项目: 国家自然科学基金(52103056)；山东省重点研发计划(重大科技创新项目)(2019 JZZY010340)

详细信息

通讯作者:
胡希丽，博士，讲师，硕士生导师，研究方向为新型功能纤维设计构筑与改性、功能纤维与智能纺织品及柔性智能可穿戴技术与医养健康 E-mail: huxili2011@163.com；

曲丽君，博士，教授，博士生导师，研究方向为柔性智能可穿戴电子器件的集成应用及石墨烯在纤维纺织品中的应用及产业化　E-mail: lijunqu@qdu.edu.cn

中图分类号: TB333
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出版历程
- 收稿日期: 2022-07-29
- 修回日期: 2022-09-24
- 录用日期: 2022-10-16
- 网络出版日期: 2022-10-19
- 刊出日期: 2023-05-15

Microfluidic spinning technology and flexible wearable application of multi-structure microfluidic fiber

College of Textiles and Clothing, Qingdao University, Qingdao 266071, China

Funds: National Natural Science Foundation of China (52103056); Shandong Province Key Research and Development Plan (Major Scientific and Technological Innovation Projects) (2019 JZZY010340)

摘要

摘要: 微流控纺丝技术融合了微流控技术和纺丝技术的优点，可设计制备常规纺丝技术难以实现的复杂结构微纤维。通过对微尺度流体流动的精确调控及利用微通道内流体的层流流动特性，微流控纺丝技术制备的多元结构功能微纤维在生物医学、柔性电子、分析化学等领域具有广泛应用。本文系统介绍了微流控纺丝技术的纺丝装置及固化机制，综述了实心/多孔纤维、中空/核壳纤维、Janus/双组分/多组分纤维、纺锤状纤维、螺旋纤维等多元结构纤维的制备方法、结构特点及其在柔性可穿戴中的应用，最后分析了微流控纺丝技术在制备微纤维中的优势与不足，并对微流控纺丝技术的应用前景进行展望。
- 微纤维 /
- 芯片 /
- 微流控纺丝 /
- 多元结构纤维 /
- 柔性可穿戴
Abstract: Microfluidic spinning technology combines the advantages of microfluidic technology and spinning technology, and can design and fabricate complex microfibers that are difficult to be realized by conventional spinning technology. Through the precise regulation of micro-scale fluid flow and the use of laminar flow characteristics of the fluid in the micro-channel, microfluidic spinning technology has a wide range of applications in biomedicine, flexible electronics, analytical chemistry and other fields. In this paper, the spinning device and curing mechanism of microfluidic spinning technology are systematically introduced, and the preparation methods, structural characteristics and applications of multi-structure fibers such as solid/porous fiber, hollow/core-shell fiber, Janus/two-component/multi-component fiber, spindle fiber and spiral fiber are reviewed. Finally, the advantages and disadvantages of microfluidic spinning technology in the preparation of microfibers are analyzed, and the application prospect of microfluidic spinning technology is forecasted.
- microfiber /
- chip /
- microfluidic spinning /
- multistructural fiber /
- flexible and wearable

HTML全文

图 1 多元结构微流控纤维及柔性可穿戴应用

NFC—Near field communication; SC—Supercapacitor

Figure 1. Multicomponent microfluidic fiber and flexible wearable applications

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图 2 微流控芯片制备材料^[21]

PDMS—Polydimethylsiloxane; PS—Polystyrene; GFP—Green fluorescent protein

Figure 2. Preparation materials of microfluidic chip^[21]

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图 3 微流控制备纤维固化原理示意图^[30]：(a)光聚合；(b)化学交联；(c)离子交联；(d)溶剂交换；(e)非溶剂诱导的相分离；(f)溶剂蒸发

Figure 3. Schematic diagram of curing principle of microfluidic controlled standby fiber^[30]: (a) Photopolymerization; (b) Chemical crosslinking; (c) Ionic crosslinking; (d) Solvent exchange; (e) Non-solvent induced phase separation; (f) Solvent vaporing

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图 4 (a) 碳纳米枝/聚氨酯(CNBs/TPU)纤维制造的示意图^[37]；(b) 具有荧光和储能能力的CNBs的制造示意图^[38]；(c) 分层多孔石墨烯纤维组装织物(HP-GFF)的微流控组装及基于织物的超级电容器的构建及其应用^[39]；(d) 石墨烯中氮掺杂机制及制备N掺杂的多孔石墨烯纤维的示意图^[41]

UV—Ultraviolet; GO—Graphite oxide; P-GO—Porous-graphite oxide; GOFF—Graphite oxide fiber-assembled fabric; PVA—Polyvinyl alcohol; rGO—Reduced-graphite oxide; MGFs—Microfluidic-directed graphene fibers

Figure 4. (a) Schematic diagram of carbon nanobranches/thermoplastic polyurethane (CNBs/TPU) fiber manufacturing^[37]; (b) Schematic diagram of manufacturing CNBs with fluorescent and energy storage capabilities^[38]; (c) Microfluidic assembly of hierarchical porous graphene fibers-assembled fabric (HP-GFF) and construction and application of fabric-based supercapacitors^[39]; (d) Schematic diagram of nitrogen doping mechanisms in graphene and preparation of N-doped porous graphene fibers^[41]

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图 5 (a)用于电子皮肤的具有MXene封装的形态水凝胶超细纤维的示意图^[42]；(b)双中空与薄带状纤维的制备^[43]；(c)具有中空螺旋结构的磁性混合微型游泳器的微流体制造示意图^[44]

Q—Quantity of flow; NaAlg—Sodium alginate; PEG-DA—Poly(ethylene glycol) diacrylate; PI—Photoinitiator

Figure 5. (a) Schematic diagram of morphologic hydrogel microfiber with MXene encapsulation for electronic skin^[42]; (b) Preparation of double hollow and thin ribbon fibers^[43]; (c) Schematic diagram of microfluidics manufacturing of magnetic hybrid micro-swimmer with hollow spiral structure^[44]

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图 6 (a)用于超级电容器的仿生多组分碳纳米管微纤维的示意图^[46]；(b)液态金属(LM)集成微纤维的制备装置和过程及所产生的中空和LM集成微纤维图^[47]；(c)氧化镍/石墨烯多孔核壳纤维的制备机制及应用^[48]；(d)碳纳米管–藻酸盐纤维的制造与微流控纺丝装置^[49]

PU—Polyurethane; CNTs—Carbon nanotubes; PS-G3 PAMAM—Polystyrene-generation 3 polyamidoamine; FSMSC—Fiber-shaped micro-supercapacitor; VA-Ni(OH)₂NSs—Vertically aligned Ni(OH)₂ nanosheets; VA-NiO NSs—Vertically aligned NiO nanosheets; P-GF—Porous graphene fiber

Figure 6. (a) Schematic diagram of biomimetic multi-component carbon nanotube microfibers for supercapacitors^[46]; (b) Liquid metal (LM)-integrated microfiber preparation device and process and diagrams of hollow and LM-integrated microfibers generated^[47]; (c) Preparation mechanism and application of nickel oxide/graphene porous core-shell fibers^[48]; (d) Fabrication of carbon nanotubule-alginate fibers and microfluidic spinning devices^[49]

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图 7 (a) Janus双层水凝胶纤维制备及SEM图像^[50]；(b)通过流动辅助动态双重交联策略制备全纤维素分级海绵气凝胶纤维(CGFs)^[51]；(c)同轴层流微流控纺丝装置示意图及水凝胶纤维横截面的SEM图像^[52]

SA—Sodium alginate; AM—Acrylamide; BIS—N, N′-methylenebisacrylamide; KPS—Potassium peroxodisulfate; TEMED—N, N, N′, N′-tetramethylethylenediamine; d—Diameter

Figure 7. (a) Preparation and SEM images of Janus double-layer hydrogel fiber^[50]; (b) Customization of all-cellulose graded sponge-aerogel fibers (CGFs) through a flow-assisted dynamic dual-cross-linking strategy^[51]; (c) Schematic of the coaxial laminar flow microﬂuidic spinning device and SEM image of the cross-section of the hydrogel ﬁber^[52]

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图 8 (a) 制备海藻酸钙纺锤结纤维的示意图^[53]；(b)水包气微流控方法制造的具有仿生纺锤结微纤维^[54]；(c)制造纺锤结微纤维的毛细管微流控系统的示意图及捕雾和热触发水收集性能^[55]

CCD—Charge coupled device

Figure 8. (a) Schematic of preparation of calcium alginate fusion-bonded fibers^[53]; (b) Bionic spindle junction microfibers manufactured by water vapor microfluidic method^[54]; (c) Schematic drawings of capillary microfluidic systems for the manufacture of fusion-junction microfibers and their fog-trapping and heat-triggered water collection properties^[55]

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图 9 (a)制备螺旋纤维的同轴毛细管微流控装置及应用^[57]；(b)微流控制造的用于柔性电子的仿生微弹簧的示意图及对各种人体运动的电导率响应^[58]；(c)用于生成聚合物螺旋微纤维的毛细管微流控装置的示意图^[59]；(d)具有套筒层的微流控装置和螺旋微纤维制造示意图^[60]

d—Diameter; l—Length; A—Amplitude; λ—Wavelength; CCS—Carboxylated chitosan; PVA—Polyvinyl alcohol; EVOH—Ethylene-vinyl alcohol copolymer; PUU3-12—Amphiphilic linear polyurethane-urea; α, β, γ—Angle; R₀—Initial resistance of the sensor; R—Resistance during stretching

Figure 9. (a) Coaxial capillary microfluidic device for helical fiber preparation and its application^[57]; (b) Schematic diagram of bionic micro-springs for flexible electrons built by microflow control and conductivity response to various human movements^[58]; (c) Schematic diagram of a capillary microfluidic device for generating polymer helical microfibers^[59]; (d) Schematic diagram of microfluidic device with sleeve layer and spiral microfiber manufacturing^[60]

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