Arced Multi-Nozzle Electrospinning Spinneret for High-Throughput Production of Nanofibers

Jiang, Jiaxin; Zheng, Gaofeng; Xiang, Wang; Li, Wenwang; Kang, Guoyi; Chen, Huatan; Guo, Shumin; Liu, Juan

doi:10.3390/mi11010027

Cited by 18 publications

(8 citation statements)

References 16 publications

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“…Attaching a metal needle to the end of the syringe, and charging (or grounding) the needle fulfils the basic feed requirements for electrospinning and is often as far as researchers need to go for proof-of-concept studies [18][19][20][21][22][23], or basic morphology work [24][25][26][27][28]. An extension of this method is to utilize multiple needles on the same syringe pump to increase the material throughput and the electrospinning footprint on the collector [29][30][31].…”

Section: Feedmentioning

confidence: 99%

Electrospinning as a route to advanced carbon fibre materials for selected low-temperature electrochemical devices: A review

Wen

Kok

Tafoya

et al. 2021

Journal of Energy Chemistry

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Section: Feedmentioning

confidence: 99%

Electrospinning as a route to advanced carbon fibre materials for selected low-temperature electrochemical devices: A review

Wen

Kok

Tafoya

et al. 2021

Journal of Energy Chemistry

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“…Therefore, different arrangements may be applied to the needles such as one-dimensional linear configuration or two-dimensional configurations such as elliptical, circular, triangular, square and hexagonal [ 65 , 74 ]. An arced multi-nozzle spinneret was designed to increase the production efficiency of electrospinning, resulting in relatively uniform electrical fields which in turn decreases the electrical interference of the needles and subsequently improves nanofiber quality [ 75 ]. The following are some examples for applying this technology for drug delivery and the pharmaceutical industry: an electro-spun formulation containing galactosidase as a model biopharmaceutical drug has been successfully developed through using scaled-up electrospinning experiments of a lab-scale, high-speed electrostatic spinning (HSES) setup consisting of a circular-shaped, stainless steel spinneret, equipped with eight orifices, and connected to a high-speed motor.…”

Section: Up-scaling Of Nanofiber Productionmentioning

confidence: 99%

Scale-up of Electrospinning: Market Overview of Products and Devices for Pharmaceutical and Biomedical Purposes

et al. 2021

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Recently, the electrospinning (ES) process has been extensively studied due to its potential applications in various fields, particularly pharmaceutical and biomedical purposes. The production rate using typical ES technology is usually around 0.01–1 g/h, which is lower than pharmaceutical industry production requirements. Therefore, different companies have worked to develop electrospinning equipment, technological solutions, and electrospun materials into large-scale production. Different approaches have been explored to scale-up the production mainly by increasing the nanofiber jet through multiple needles, free-surface technologies, and hybrid methods that use an additional energy source. Among them, needleless and centrifugal methods have gained the most attention and applications. Besides, the production rate reached (450 g/h in some cases) makes these methods feasible in the pharmaceutical industry. The present study overviews and compares the most recent ES approaches successfully developed for nanofibers’ large-scale production and accompanying challenges with some examples of applied approaches in drug delivery systems. Besides, various types of commercial products and devices released to the markets have been mentioned.

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“…The electrospun nanofibrous membrane was fabricated by the previous reported method of multi-jet electrospinning with sheath gas [49][50][51][52], as shown in figure 1. The sheath gas in the laminar flow is helpful to overcome the electrical interferences among nozzles and to promote the stability of multijet electrospinning process.…”

Section: Preparation Of Nanofibrous Membranementioning

confidence: 99%

Three-dimensional composite electrospun nanofibrous membrane by multi-jet electrospinning with sheath gas for high-efficiency antibiosis air filtration

et al. 2021

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Three-dimensional (3D) composite polyvinylidene fluoride (PVDF)/polyacrylonitrile (PAN) electrospun nanofibrous membranes combining both thick and thin nanofibers have been fabricated by the method of multi-jet electrospinning with sheath gas to realize high-efficiency air filtration under a low pressure drop. The thin PAN nanofibers form a dense membrane, with a strong capturing ability on the ultra-fine particles, while the thick PVDF nanofibers play a 3D supporting effect on the thin PAN nanofibers. In this case, the combination results in a fluffy membrane with higher porosity, which could achieve the airflow passing through the membrane without the air pressure drop. The effects of the composite manner of thick nanofibers and thin nanofibers are investigated, in order to optimize the air filtration performance of the 3D composite nanofibrous membrane. As a result, the maximum quality factor for air filtration could reach up to 0.398 Pa−1. The particle-fiber interaction model was used to simulate the air filtration process as well, and the simulation results were fairly consistent with the experimental results, providing a guidance method for the optimization of composite nanofibrous membrane for high-efficiency air filtration. More interestingly, a cationic poly[2-(N,N-dimethyl amino) ethyl methacrylate] (PDMAEMA) was added in the PVDF solution to obtain a composite air filtration membrane with excellent antibiosis performance, which achieved the highest inhibition rate of approximately 90%. In short, this work provides an effective way to promote antibiosis air filtration performance by using an electrospun nanofibrous membrane, and might also effectively accelerate the biological protection application of current air filtration membranes.

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Arced Multi-Nozzle Electrospinning Spinneret for High-Throughput Production of Nanofibers

Cited by 18 publications

References 16 publications

Electrospinning as a route to advanced carbon fibre materials for selected low-temperature electrochemical devices: A review

Electrospinning as a route to advanced carbon fibre materials for selected low-temperature electrochemical devices: A review

Scale-up of Electrospinning: Market Overview of Products and Devices for Pharmaceutical and Biomedical Purposes

Three-dimensional composite electrospun nanofibrous membrane by multi-jet electrospinning with sheath gas for high-efficiency antibiosis air filtration

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