1、Facile fabrication of fluorine
In this paper, fluorine-free poly (styrene-b-butadiene-b-styrene) (SBS), polyurethane (PU), and 2-hydroxy-4-n-octyloxy benzophenone (UV531) were selected to prepare multi-functional nanofiber membranes by convenient one-step electrospinning.
2、Preparation of fluorine
To develop a fluorine-free material of acidproof and breathable fabric, styrene–butadiene–styrene (SBS) blended with pitch was directly deposited on polyester/cotton blended fabric through electrospinning to fabricate a nanofibrous membrane composite fabric.
3、Multifunctional, Waterproof, and Breathable Nanofibrous Textiles Based
Here, an environmentally benign fluorine-free, ultraviolet (UV) blocking, and antibacterial WBM with a high level of waterproofness and breathability is developed on a large scale by combining electrospinning and step-by-step surface coating technology.
Sci
Preparation of fluorine-free anti-acid and breathable composite fabric based on modified SBS/pitch electrospun nanofibers. Textile Research Journal, 91 (13-14), 1535–1545. doi:10.1177/0040517520982588.
The Modification Mechanism, Evaluation Method, and Construction
From the evaluation of the modification effect, the method of studying the performance of direct-to-plant SBS-modified asphalt is summarized, including fluorescence microscopy, AFM technology, and molecular dynamics simulation technology.
Preparation of fluorine
To develop a fluorine-free material of acidproof and breathable fabric, styrene–butadiene–styrene (SBS) blended with pitch was directly deposited on polyester/cotton blended fabric through...
Preparation of fluorine
To develop a fluorine-free material of acidproof and breathable fabric, styrene–butadiene–styrene (SBS) blended with pitch was directly deposited on polyester/cotton blended fabric through electrospinning to fabricate a nanofibrous membrane composite fabric.
Developing an acidproof breathable composite fabric based on
To develop a fluorine-free material of acidproof and breathable fabric, styrene–butadiene–styrene (SBS) blended with pitch was directly deposited on polyester/cotton blended fabric through…
Study on the resourceful reuse in SBS
In contrast to traditional chemical modification, this study reports a new method for the hydrophobic modification of BFs using tannic acid (TA) and the in situ growth of FeOOH nanoparticles (NPs), resulting in FeOOH-TA-BF, which is used to prepare styrene–butadiene styrene (SBS)–modified asphalt.
Advancing eco
To advance sustainable and health-conscious pavement technologies, this study aims to develop eco-friendly styrene–butadiene–styrene modified asphalt with sustainable solutions, focusing on performance, mechanisms, and the environmental and health risk assessment of bio-based activated carbon powder (ACP) and expanded graphite (EG) modifications...
In the vast field of modern polymer material science, the composite application of fluoropolymers and SBS (styrene-butadiene-styrene) has become a hot topic. This composite material not only exhibits excellent physical and chemical properties but also demonstrates significant potential in numerous industrial applications. This paper aims to explore the modification effects of fluoropolymers on SBS and the impact of such modifications on material performance.
SBS is a common rubber-like polymer known for its good elasticity, wear resistance, and processability. its poor thermal stability limits its application in high-temperature environments. To enhance the performance of SBS, researchers have developed various modification methods, including the introduction of fluoropolymers.
Fluoropolymers are high-performance thermoplastic plastics with exceptional chemical and oxidation resistance. Incorporating fluoropolymers into the SBS system can significantly improve the material's heat resistance, oil resistance, and chemical resistance. Additionally, fluoropolymers can enhance the processability of SBS, making it more suitable for complex molding processes.
In experimental studies, researchers mixed fluoropolymers with SBS using melt-blending techniques. Initially, fluoropolymers and SBS were pre-mixed, followed by melt-blending at high temperatures. By adjusting the fluoropolymer content, the mechanical properties, thermal stability, and processability of the modified material can be controlled.
Studies indicate that when the fluoropolymer content reaches 20%, the modified SBS exhibits optimal comprehensive performance. At this ratio, the material achieves high tensile strength, elongation at break, and hardness while maintaining good processability. Furthermore, the modified SBS demonstrates excellent oil resistance and acid-alkali resistance, making it suitable for various industrial applications.
Besides melt-blending, fluoropolymers can also be introduced into the SBS system through solution-blending or mechanical-blending methods. Each method has its advantages and disadvantages but can effectively achieve the modification of SBS. For example, solution-blending enables uniform dispersion and improves compatibility, while mechanical-blending promotes interactions between phases through shear forces.
The practical applications of fluoropolymer-modified SBS span multiple fields. In automobile manufacturing, the modified SBS can be used to produce tire sidewalls and sealing strips, enhancing temperature resistance and wear resistance. In the electronics and electrical industry, it serves as an insulating material for manufacturing circuit boards and transformers, extending service life and reducing maintenance costs. Additionally, the modified SBS is employed in consumer goods such as shoe soles and insoles, providing better comfort and durability.
challenges remain in the modification of SBS with fluoropolymers. For instance, high fluoropolymer content may increase material brittleness, affecting usability. the relatively high cost of fluoropolymers could limit their large-scale production applications. practical use requires careful selection of modification ratios and production processes based on specific needs.
fluoropolymer-modified SBS is a material with broad application prospects. By optimizing fluoropolymer content and preparation processes, the comprehensive performance of the modified material can be further improved. With advancements in technology and changing market demands, fluoropolymer-modified SBS is expected to play a greater role in future industrial development.
