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Fibers and Polymers

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08.09.2023 | Regular Article

Flow Velocity Deviation of Spinning Solution Under Multi-field Coupling

verfasst von: Zhiming Zhang, Da Hong, Xinyu Huang, Kang Liu, Qiao Xu, Zhen Chen, Qiaoling Ji, Changjin Ke

Erschienen in: Fibers and Polymers | Ausgabe 10/2023

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Abstract

Rotating jet spinning uses the centrifugal force generated by the high-speed rotation of the motor to keep the spinning solution ejected from the nozzle to form nanofibers. At present, the research work on rotating jet spinning mainly involves the materials, properties and applications of fibers, parameter influence and jet trajectory, while there are few studies on the optimization of spinning core components. In this paper, by analyzing the force and flow state of spinning solution in the flow channel of spinning nozzle, it is found that the maximum velocity region of spinning solution will be offset. The reason for this phenomenon is that the spinning solution is subjected to Coriolis force in the rotating system, resulting in the secondary flow of solution. The relationship between nozzle parameters, solution parameters as well as process parameters, and the outlet velocity of solution was sought, and the structure of spinning nozzle was optimized. The factors affecting velocity offset in straight-tube nozzles and bent-tube nozzles are simulated. High-speed centrifugal spinning experiments were conducted using both unoptimized and optimized nozzles.

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Titel: Flow Velocity Deviation of Spinning Solution Under Multi-field Coupling
verfasst von: Zhiming Zhang
Da Hong
Xinyu Huang
Kang Liu
Qiao Xu
Zhen Chen
Qiaoling Ji
Changjin Ke
Publikationsdatum: 08.09.2023
Verlag: The Korean Fiber Society
Erschienen in: Fibers and Polymers / Ausgabe 10/2023
Print ISSN: 1229-9197
Elektronische ISSN: 1875-0052
DOI: https://doi.org/10.1007/s12221-023-00349-8

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