Catalog |
name |
Description |
price |
R-R-3697 |
Polyester flexible polymer electrospinning |
Polyester flexible polymer electrospinning refers to a technique used to create ultra-fine fibers from a polymer solution or melt, with polyester being the specific type of polymer in this case. Electrospinning involves the use of electrical forces to draw charged threads of polymer solutions or melts into fibers of diameters ranging from several micrometers down to a few nanometers.Polyester flexible polymer electrospinning has various applications, including but not limited to tissue engineering, filtration, protective textiles, and drug delivery systems. The resulting ultra-fine fibers have a high surface area-to-volume ratio and can form non-woven mats or membranes with unique properties, making them suitable for a wide range of industrial and biomedical applications. |
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R-R-3698 |
Polyamide flexible polymer electrospinning |
Polyamide flexible polymer electrospinning is a process used to create ultra-fine fibers from polyamide, a type of synthetic polymer.Polyamide flexible polymer electrospinning has a diverse range of applications, including use in industries such as textiles, filtration, biomedical engineering, and nanotechnology. The resulting ultra-fine fibers possess a notably high surface area-to-volume ratio and can be formed into non-woven mats or membranes with specific properties, making them suitable for various industrial, medical, and research applications. These applications can include tissue scaffolding, filtration media, protective clothing, and drug delivery systems, among others. |
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R-R-3699 |
Polyurethane elastomer polymer electrospinning |
Polyurethane elastomer polymer electrospinning/Pu elastomer polymer electrospinning from ruixi.Polyurethane elastomer polymer electrospinning is a process used to fabricate ultra-fine fibers from polyurethane, a versatile and durable synthetic polymer known for its elastomeric properties. Polyurethane elastomer polymer electrospinning finds diverse applications, including but not limited to tissue engineering, wound dressings, filtration, protective clothing, and biomedical devices. The resulting ultra-fine fibers possess a high surface area-to-volume ratio and can be formed into non-woven mats or membranes with specific porosity, mechanical strength, and biocompatibility, making them suitable for a wide range of industrial and biomedical applications. These applications can include tissue scaffolds, wound dressings, filtration media, and drug delivery systems, among others. |
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R-R-3700 |
Nanosilver-polyacrylonitrile electrospun nanofiber felt |
Nanosilver-polyacrylonitrile electrospun nanofiber felt is a composite material formed through the electrospinning process, where polyacrylonitrile (PAN) is used as a base polymer and nanosilver particles are incorporated into the polymer matrix. This makes the nanosilver-polyacrylonitrile electrospun nanofiber felt suitable for various applications such as antimicrobial wound dressings, air filtration systems, and protective clothing. Its unique structure and composition provide a versatile platform for applications requiring both nanoscale material properties and the benefits of a fibrous, porous structure. |
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R-R-3701 |
Nisin/chitosan/polylactic acid electrospun nanofiber felt |
Nisin/chitosan/polylactic acid electrospun nanofiber felt;Nisin/chitosan/PLA electrospun nanofiber felt from ruixi.Nisin/chitosan/polylactic acid electrospun nanofiber felt is a specialized composite material formed through the electrospinning process, where polylactic acid (PLA) serves as the base polymer with the incorporation of chitosan and nisin.This makes the nisin/chitosan/polylactic acid electrospun nanofiber felt suitable for a wide range of applications such as wound dressings, tissue engineering scaffolds, food packaging materials, and filters for water and air purification. Its unique composition provides a powerful combination of antimicrobial capability and structural versatility, making it well-suited for applications demanding both antimicrobial properties and the benefits of nanofibrous structures. |
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R-R-3702 |
PSF electrospun fiber film |
PSF electrospun fiber film/Polysulfone electrospun fiber film from ruixi. Polysulfone electrospun fiber film is a specialized material created through the electrospinning process using polysulfone, a synthetic polymer known for its excellent thermal, mechanical, and chemical properties. This process involves the application of high voltage to draw charged threads of a polysulfone polymer solution, resulting in the formation of ultra-fine fibers that are then collected to form a film.Polysulfone electrospun fiber films find applications in various industries including membrane technology for filtration, tissue engineering, sensors, and protective clothing. |
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R-R-3703 |
Porous PSF nanofiber films |
Porous polysulfone nanofiber films/Porous PSF nanofiber films from ruixi. Porous polysulfone nanofiber films are specialized materials created through the electrospinning process using polysulfone, a thermoplastic polymer known for its excellent chemical resistance and mechanical properties. Porous polysulfone nanofiber films find applications in various fields such as membrane technology for liquid and gas filtration, tissue engineering scaffolds, biomedical devices, and sensors. Their unique structure provides an ideal platform for applications requiring high surface area, precise pore size control, and excellent mechanical strength, making them well-suited for industries where advanced filtration, separation, or biomedical functionalities are needed. |
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R-R-3704 |
Electrospun PSF fiber film |
Electrospun polysulfone fiber film/Electrospun PSF fiber film from ruixi. Electrospun polysulfone (PSF) fiber film refers to a specialized material produced through the electrospinning process, which involves the use of polysulfone, a high-performance engineering thermoplastic. The electrospinning process involves the application of a high voltage to draw charged threads from a polysulfone polymer solution. These threads form ultra-fine nanoscale fibers that are collected to create a film. The resulting film exhibits a highly porous structure, characterized by an interconnected network of nanofibers. The unique morphology of electrospun PSF fiber films provides them with a high surface area and tunable porosity.These films find a broad range of applications, including but not limited to, membrane technology for filtration, tissue engineering, biomedical devices, and protective coatings. The combination of high surface area, porosity, and mechanical strength makes electrospun PSF fiber films well-suited for applications that require precise control over permeability, surface area, and mechanical properties, particularly in areas involving filtration, separation, or biomedical uses. |
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R-R-3705 |
Mesoporous PSF electrospun fiber film |
Mesoporous polysulfone electrospun fiber film/Mesoporous PSF electrospun fiber film from ruixi. Mesoporous polysulfone (PSF) electrospun fiber film is a specialized material formed through a combination of electrospinning and a subsequent treatment to introduce mesopores within the structure. Polysulfone, a high-performance thermoplastic polymer, is used as the base material for the electrospinning process. The resulting nanofiber thin film, in this case, possesses an interconnected network of ultra-fine fibers with added mesopores, providing additional surface area and pore volume.Mesoporous PSF electrospun fiber thin films are well-suited for applications requiring advanced filtration, separation, or adsorption properties. |
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R-R-3706 |
Porous PAN nanofiber film |
Porous polyacrylonitrile nanofiber film/Porous PAN nanofiber film from ruici. Porous polyacrylonitrile nanofiber film is a specialized material created through the electrospinning process using polyacrylonitrile (PAN), a synthetic polymer with excellent chemical and thermal properties. Porous polyacrylonitrile nanofiber films find applications in various industries including filtration membranes, tissue engineering scaffolds, protective clothing, and in the development of sensors. Their unique structure makes them suitable for applications requiring high surface area, precise pore size control, and excellent mechanical strength. These properties are particularly advantageous in fields that demand advanced filtration, separation, or biomedical functionality. |
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