Comparison of the physical properties of heat-treated and hydrophobic modified glass fiber felt

Wang, Feiyan; Yu, Jianyong; Ge, Aixiong; Liang, Xunmei; Lu, Shide; Zhao, Chunfeng; Liu, Lifang

doi:10.1177/1528083720988479

Cited by 4 publications

(2 citation statements)

References 28 publications

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“…The higher the temperature, the flatter the fibers [ 32 ]. The opening between the fibers was, thus, reduced due to the heat-induced contraction of the nanofibers [ 33 ]. Consequently, the mean pore size of the ENF support was significantly decreased with heat press temperatures, contributing to an increase in the pressure required for determining the mean pore size ( Table 1 ).…”

Section: Resultsmentioning

confidence: 99%

Evaluating Post-Treatment Effects on Electrospun Nanofiber as a Support for Polyamide Thin-Film Formation

Augusty,

Rangkupan,

Klaysom

2024

Polymers

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Poly(acrylonitrile-co-methyl acrylate) (PAN-co-MA) electrospun nanofiber (ENF) was used as the support for the formation of polyamide (PA) thin films. The ENF support layer was post-treated with heat-pressed treatment followed by NaOH hydrolysis to modify its support characteristics. The influence of heat-pressed conditions and NaOH hydrolysis on the support morphology and porosity, thin-film formation, surface chemistry, and membrane performances were investigated. This study revealed that applying heat-pressing followed by hydrolysis significantly enhances the physicochemical properties of the support material and aids in forming a uniform polyamide (PA) thin selective layer. Heat-pressing effectively densifies the support surface and reduces pore size, which is crucial for the even formation of the PA-selective layer. Additionally, the hydrolysis of the support increases its hydrophilicity and decreases pore size, leading to higher sodium chloride (NaCl) rejection rates and improved water permeance. When compared with membranes that underwent only heat-pressing, those treated with both heat-pressing and hydrolysis exhibited superior separation performance, with NaCl rejection rates rising from 83% to 98% while maintaining water permeance. Moreover, water permeance was further increased by 29% through n-hexane-rinsing post-interfacial polymerization. Thus, this simple yet effective combination of heat-pressing and hydrolysis presents a promising approach for developing high-performance thin-film nanocomposite (TFNC) membranes.

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Section: Resultsmentioning

confidence: 99%

Evaluating Post-Treatment Effects on Electrospun Nanofiber as a Support for Polyamide Thin-Film Formation

Augusty,

Rangkupan,

Klaysom

2024

Polymers

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“…Glass fiber (GF) is a cotton-like material obtained by fibrosis of molten glass [ 1 ]. It is an inorganic, nonmetallic material with a number of excellent properties, such as a high aspect ratio, small volume density, low thermal conductivity, strong corrosion resistance, stable chemical performance, and electrical insulation [ 2 , 3 , 4 , 5 , 6 , 7 ]. It has become an important adsorbent in the field of chemistry and an important new, lightweight, and energy-saving composite multifunctional carrier.…”

Section: Introductionmentioning

confidence: 99%

Recent Progress in Modifications, Properties, and Practical Applications of Glass Fiber

Song

et al. 2023

Molecules

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As a new member of the silica-derivative family, modified glass fiber (MGF) has attracted extensive attention because of its excellent properties and potential applications. Surface modification of glass fiber (GF) greatly changes its performance, resulting in a series of changes to its surface structure, wettability, electrical properties, mechanical properties, and stability. This article summarizes the latest research progress in MGF, including the different modification methods, the various properties, and their advanced applications in different fields. Finally, the challenges and possible solutions were provided for future investigations of MGF.

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Glass fiber reinforced PA6 composites with high strength and high flowability by hyperbranched polyesters

Liang,

Hu,

Cheng

et al. 2024

Journal of Polymer Science

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Lightweighting of automotives is one of the efficient strategies to save energy and reduce CO2 emission and environmental pollution. Glass fiber reinforced polyamide composites (PA/GF) have accounted for about 20% of plastic composites for automotives, showing a large potential to replace metal materials. However, it is an imperative challenge to prepare high‐strength and rapid‐processing PA/GF composites due to poor compatibility between GF and PA. Here, we have synthesized amphiphilic hyperbranched polyesters (H24‐m) containing long aliphatic chains and hydroxyl groups by esterification between hydroxyl‐ended hyperbranched polyester (H24) and stearoyl chloride (SC), which are used to prepare high‐performance GF/PA6 composites. Influence factors on the mechanical properties and melt flow index (MFI) of PA6/GF composites have also been investigated, including GF content, H24‐50 content, esterification degree of H24, and the ratio of H24‐50 to carboxyl‐ended hyperbranched polymer (HyPer C100). The obtained C100/H24‐50/PA6/GF composites show simultaneously high strength, super toughness, high MFI, and high GF content of about 60 wt%. A dispersion‐bridging‐interfacial improvement mechanism has been discovered deeply by investigating crystal behavior, rheological behavior, hydrogen bond interaction, GF length variation, and the synergistic effect of amphiphilic hyperbranched polyester and HyPer C100. This work provides a simple approach to fabricating high‐performance GF/PA6 composites for extensive application in automotive parts, showing great prospects in the lightweight of automotives.

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Comparison of the physical properties of heat-treated and hydrophobic modified glass fiber felt

Cited by 4 publications

References 28 publications

Evaluating Post-Treatment Effects on Electrospun Nanofiber as a Support for Polyamide Thin-Film Formation

Evaluating Post-Treatment Effects on Electrospun Nanofiber as a Support for Polyamide Thin-Film Formation

Recent Progress in Modifications, Properties, and Practical Applications of Glass Fiber

Glass fiber reinforced PA6 composites with high strength and high flowability by hyperbranched polyesters

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